Systems and methods for decompression, elliptical traction, and linear traction of the occiput, cervical spine, and thoracic spine

ABSTRACT

A traction device has a frame, a first bladder portion, a second bladder portion, and a third inflatable bladder portion. The first bladder expands in an outward direction a distance greater than in a transverse direction. The second bladder expands in a first angular direction. The second bladder is positioned generally inferior to and to the side of the first bladder. The third bladder expands in a second angular direction. Upon expanding in the outward direction, the first bladder bears against the back of the user&#39;s neck. Upon expanding in the transverse direction, the first bladder applies an angular traction to the cervical spine. Upon expanding in the first angular direction, the second bladder bears angularly against the back of the user&#39;s upper thoracic region. Upon expanding in the third angular direction, the third bladder bears angularly against the user&#39;s occiput.

CROSS-REFERENCE TO RELATED APPLICATIONS

Any and all applications for which a foreign or domestic priority claim is identified in the Application Data Sheet as filed with the present application, are hereby incorporated by reference under 37 CFR 1.57.

BACKGROUND Field

Disclosed herein are spinal decompression and traction systems and methods related to the field of spinal treatment. More particularly, certain embodiments disclosed herein relate to occipital, cervical and thoracic spinal decompression and traction systems having a plurality of inflatable bladders and methods of use that maintain, enhance and restore a normal lordotic curve and counter hyper-kyphosis of the upper and mid thoracic spine.

Description of the Related Art

Cervical pain is one of the most common health-related complaints. When there are no neurological deficits, symptomatic relief of pain is often sought with either non-steroidal analgesics, or various physical therapy modalities, including cervical traction. Most traction has consisted of axial linear distraction employing various head/chin straps and weights of 20 to 25 pounds. Such traction tends to straighten the cervical spine, removing its normal curve and often results in TMJ pain.

The undamaged cervical spine normally defines a forward or lordotic curve of about 43° (measured from C2-C7) whereby weight is distributed on hard individual bony articular surfaces in the posterior and soft intervertebral discs to the anterior. Without such a forward curve in the cervical spine, weight of the head transfers forward onto the soft non-bony intervertebral discs and vertebral bodies causing discs to dehydrate, wear, degenerate and protrude into the anterior subarachnoid space. As vertebral bodies bear uneven stress, spurs and osteophytes form. Additionally, individuals with lost or reversed (buckled) cervical spinal curves eventually exhibit a significant loss of natural joint movement, further limiting the normal canaliculus seepage and imbibition of adjacent fluids via vertebral end plates and annuli. Without such nutrient rich fluids the discs continue to dehydrate, further weakening the discs, resulting in a further loss of mobility, degeneration and possible nerve damage. Active nutrient transport is particularly important because the intervertebral discs' indigenous vascular supply often disappears at approximately 20 years of age.

Further, as the cervical spine is forced into flexion and the lordotic curve is reversed, the dura, cord and nerve-roots are drawn out; the root-sleeves come into contact with the pedicles, and the nerve roots with the inner surfaces of the sleeves. During extension (lordotic curve recovery) the dura, cord and nerve-roots in the cervical canal are slack; the root-sleeves have lost contact with the pedicles and the nerve-roots with the inner surfaces of the sleeves.

Axial/Linear/Longitudinal traction has long been employed to decompress cervical joints of the spine. Typically the head is pulled, pried, lifted or otherwise separated from the thorax along the Y axis (+Y axis translation or elevation translation). Ostensibly, to pry the joints apart at the posterior, forward flexion (+X axis rotation) is often employed in conjunction with or as an unavoidable component of linear traction. Linear traction or elevation translation applied to a curved column decreases or removes the curve. Likewise, adding the component of flexion or +rotation about the X axis, would apply a buckling force to the cervical spine and have the effect of reversing the curve (−Z axis translation). These forces, powerful enough to separate the spinal joints, are unfortunately antithetical to the natural geometry and biomechanics of the human cervical spine. The anchor points commonly used in Axial/Linear/Longitudinal traction are the head as it is pulled away from the thorax and/or the trapezius muscles as the thorax is pushed away from the restrained head. U.S. Pat. No. 4,805,603 to Cumberland describes a method where the head and thorax are separated by two platforms with an expanding air chamber between the two platforms. These methods, due to their linear function reduce, remove or reverse the proper cervical curve. U.S. Pat. No. 6,506,174 to Saunders also describes a linear traction system.

Some alternatives to axial/linear/longitudinal traction for disc, joint and nerve decompression seek to maintain a normal lordotic curve. For example, U.S. Pat. Nos. 5,382,226; 5,569,176; 5,713,841; 5,906,586; 7,060,085; 8,029,453; and D508,566S to Graham, each of which is hereby incorporated by reference herein in its entirety, disclose some embodiments of systems for decompression. In two IRB approved studies utilizing multiple MRI's, an embodiment of the disclosed systems showed a consistent ability to draw bulging disc material back toward the disc proper and away from the subarachnoid space and spinal cord while simultaneously enhancing or restoring the cervical lordotic curve during and after one 20 minute treatment. Patients reported immediate symptomatic relief of cervical pain. However, there exists a need for improved decompression systems that also address hyper-kyphosis of the upper thoracic spine, mid thoracic spine and compression of the occipital-cervical junction.

SUMMARY

Described herein are some embodiments of decompression and traction systems that maintain, enhance and restore a normal lordotic curve, counter hyper-kyphosis of the upper and mid thoracic spine and decompress the occipital-cervical junction. Methods of assembling and using the decompression and traction systems described herein are also included. These decompression and traction systems and related methods are described in greater detail below.

One aspect of the present invention is the recognition that traditionally available traction systems do not provide devices, systems and methods that simultaneously address cervical lordotic curve loss/reversal (hypolordosis/kyphosis), and the often accompanying posterior (−Z) translation (hyper-kyphosis) of the upper thoracic spine. Embodiments and methods described herein preferably provide pneumatic radial decompression and traction equipment for treatment of the cervical and thoracic spine including a free-standing frame, first and second expandable bladders, the first expandable bladder providing positive pressure to support a cervical spinal portion in a normal lordotic curve configuration, and the second expandable bladder providing positive pressure to support a thoracic spinal portion in a normal curve configuration to counter hyper-kyphosis of the upper thoracic spine.

According to certain embodiments of the invention, devices, systems and methods are described that simultaneously address cervical lordotic curve loss/reversal (hypolordosis/kyphosis), and the often accompanying posterior (−Z) translation (hyper-kyphosis) of the upper thoracic spine.

In relation to the head and neck, −Z translation of the upper thoracic spine is an integral part of anterior or “Forward Head Carriage.” As the head shifts forward and/or the upper thoracic spine moves posterior, the weight of the head and neck, approximately 15 pounds, creates a forward buckling force (−Y and +Z combination) on the thoracic spine. This continuous forward and downward force begets more forward head carriage and more compressive action to the cervical and thoracic intervertebral discs and bodies. Many are familiar with the term “Dowagers Hump” where hyper kyphosis of the thoracic spine is so pronounced as to be obvious with the naked eye. While approximately 30% of these postural defects (especially in women) are said to be caused by anterior thoracic vertebral body fractures due to osteoporosis, most hyper-kyphotic postures are developed over time by continuous anterior and downward force on the cervical and thoracic intervertebral discs and vertebral bodies.

As people spend long hours crouched in front of computer screens, wear heavy back packs, are involved whiplash type auto and sports injuries, forward head posture with associated cervical curve loss, and hyper thoracic kyphosis has become more prevalent. Neck and back pain, muscle tension and spasm, headaches, neuropathies and degenerative vertebral joint disease result from continuous cervical-thoracic disc and joint compression. While there have been elastic bands and braces applied to the spine to pull or hold it upright in an attempt to ameliorate worsening posture, results are mixed.

In some embodiments, the devices, systems and methods described herein apply pneumatic forces directly to the offending spinal apexes in opposing directions. With the simultaneous application of two separate air cells or pneumatic air chambers the cervical spine is locked and powerfully decompressed into its proper lordotic or curved configuration (<^>) with −Y+Z+Y force vectors while the hyper kyphotic area of the upper thoracic spine is simultaneously decompressed with a combination +Z/−Y force mid-vector. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the thoracic hyper-kyphosis is simultaneously reduced. In some embodiments, a two pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. In some embodiments, a complex multi vectored pneumatic air chamber can be used in place of two individual cells. In some embodiments, the devices, systems and methods described herein use the entire cervical spine including the occiput (base of skull) as a first anchor point and the upper thoracic spine as a second point. The pneumatic air chambers can directly contact the cervical spine/occiput and the upper 25% of the thoracic spine.

According to one embodiment, a traction device comprises a frame, a first bladder portion, a second bladder portion, a strap, and a pump. The first bladder expands in an outward direction a distance greater than in a transverse direction. The second bladder expands in an angular direction. The second bladder is positioned generally below and to the side of the first bladder. The frame is secured to the user's head. Upon expanding in the outward direction, the first bladder bears against the back of the user's neck and forces the cervical spine to curve forwardly. Upon expanding in the transverse direction, the first bladder applies an angular traction to the cervical spine. Upon expanding in the angular direction, the second bladder bears angularly against the back of the user's upper thoracic region and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine.

In certain embodiments, a traction device for imparting a forward curve to the cervical spine and reducing hyper-kyphosis of the upper thoracic spine is provided. The device comprises a frame adapted to be supported on a rigid support surface. The frame is configured to be disposed about a user's head and neck and defines contact surfaces for abutting the rigid support surface. The frame has a neck support extending between first and second side portions of the frame. A first inflatable elongated bladder is coupled to the neck support and configured to be positioned below a neck of a user during use. The first inflatable elongated bladder is expandable in a first direction outwardly from the neck support toward the neck of a user and expandable in a second direction substantially normal to the first direction upon inflation. A second inflatable elongated bladder is coupled to the neck support and configured to be positioned below the upper thoracic region of a user during use. The second inflatable elongated bladder is expandable in a third direction angularly from the neck support toward the upper thoracic spine of a user upon inflation. A securing strap is coupled to the frame and configured to secure the frame to the user's head such that the first inflatable elongated bladder is disposed adjacent the back of the user's neck and transverses the cervical spine such that the first direction of expansion is toward and substantially normal to the cervical spine. The second inflatable elongated bladder is disposed adjacent the back of the user's upper thoracic region and transverses the upper thoracic spine such that the third direction of expansion is toward and substantially normal to the upper thoracic spine. A pump system is provided for selectively inflating and deflating the first and second inflatable elongated bladders. Upon the first inflatable bladder expanding in the first direction, the first inflatable bladder bears outwardly against the back of the user's neck and forces the cervical spine to curve forwardly. Upon expanding in the second direction, the first inflatable bladder applies an angular traction to the cervical spine. Upon the second inflatable bladder expanding in the third direction, the second inflatable bladder bears angularly against the back of the user's upper thoracic region and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine.

In some embodiments, the traction device comprises a valve positioned in communication with the pump system and the first and second inflatable elongated bladders. The valve comprises varying lumen diameters that direct flow between the pump system and the first and second inflatable elongated bladders. The first inflatable elongated bladder is pivotably coupled to the neck support. A spacer is configured to be coupled between a portion of the frame and the second inflatable elongated bladder to adjust the angulation of the second inflatable elongated bladder during inflation.

In other embodiments, a traction device is provided for imparting a forward curve to the cervical spine and reducing hyper-kyphosis of the upper thoracic spine. The device comprises a frame having a transverse neck support projecting upwardly from first and second side portions defining a base of the frame. A first inflatable bladder portion is coupled to the neck support. The first inflatable bladder portion is configured to expand in an outward direction from the neck support a distance greater than the expansion of the first inflatable bladder portion in a transverse direction normal thereto. A second inflatable bladder portion is coupled to the neck support. The second inflatable bladder portion is configured to expand in an angular direction from the neck support. The second inflatable bladder portion is positioned generally below and to the side relative to the first inflatable bladder portion. A strap is coupled to the frame and configured to secure the frame to the user's head such that the first inflatable bladder portion is disposed adjacent the back of the user's neck and transverses the cervical spine such that the outward direction of expansion is toward and substantially normal to the cervical spine. The second inflatable bladder portion is disposed adjacent the back of the user's upper thoracic region and transverses the upper thoracic spine such that the angular direction of expansion is toward and substantially normal to the upper thoracic spine. A pump system is provided for inflating the first and second inflatable bladder portions. Upon the first inflatable bladder portion expanding in the outward direction, the first inflatable bladder portion bears outwardly against the back of the user's neck and forces the cervical spine to curve forwardly. Upon expanding in the transverse direction, the first inflatable bladder portion applies an angular traction to the cervical spine. Upon the second inflatable bladder portion expanding in the angular direction, the second inflatable bladder portion bears angularly against the back of the user's upper thoracic region and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine.

In some embodiments, a method is provided for imparting a forward curve to the cervical spine and reducing hyper-kyphosis of the upper thoracic spine. The method comprises securing a traction device to a user's head. The traction device comprises a support frame having a transverse neck support projecting upwardly from a base of the support frame and first and second inflatable bladder portions coupled to the neck support. The traction device is secured to the user's head includes positioning the traction device such that the first inflatable bladder portion transverses the cervical spine, and such that the second inflatable bladder portion transverses the upper thoracic spine. The first inflatable bladder portion is expanded in a direction outward from the neck support and toward and substantially normal to the cervical spine to force the cervical spine to curve forwardly. The first inflatable bladder portion is expanded in a transverse direction to apply an angular traction to the cervical spine. The second inflatable bladder portion is expanded in a direction toward and substantially normal to the upper thoracic spine to force the upper thoracic spine to decompress and reduce hyper-kyphosis of the upper thoracic spine.

In certain embodiments, methods may comprise alternately inflating and deflating the first and second bladder portions. Inflation and deflation of the first and second bladder portions can be repeated. The first inflatable bladder portion can have a semi-ellipsoidal configuration upon inflation. The second inflatable bladder portion can have a semi-ellipsoidal configuration upon inflation. During inflation or deflation, flow can be directed between the pump system and the bladder portion through a valve that comprises different lumen diameters to provide particular flow to or from the first and second inflatable bladder portions. Methods can include pivoting the first inflatable bladder relative to the neck support and/or positioning a spacer between a portion of the frame and the second inflatable bladder portion to adjust the angulation of the second inflatable bladder portion during inflation.

In some embodiments, a traction device is provided for imparting a forward curve to the cervical spine and reducing hyper-kyphosis of the upper thoracic spine. The device comprises a frame adapted to be supported on a rigid support surface. The frame is configured to be disposed about a user's head and neck and defines contact surfaces for abutting the rigid support surface. The frame has a neck support extending between first and second side portions of the frame. A first inflatable elongated bladder is coupled to the neck support and configured to be positioned below a neck of a user during use. The first inflatable elongated bladder is expandable in a first direction outwardly from the neck support toward the neck of a user and expandable in a second direction substantially normal to the first direction upon inflation. A second inflatable elongated bladder is coupled to the neck support and configured to be positioned below the upper thoracic region of a user during use. The second inflatable elongated bladder is expandable in a third direction angularly from the neck support toward the upper thoracic spine of a user upon inflation. A spacer is configured to be coupled between a portion of the frame and the second inflatable elongated bladder to adjust the angulation of the second inflatable elongated bladder during inflation. A pump system is provided for selectively inflating and deflating the first and second inflatable elongated bladders. Upon the first inflatable bladder expanding in the first direction, the first inflatable bladder bears outwardly against the back of the user's neck, and upon expanding in the second direction, the first inflatable bladder applies an angular traction to the cervical spine. Upon the second inflatable bladder expanding in the third direction, the second inflatable bladder bears angularly against the back of the user's upper thoracic region.

In certain embodiments, a traction device for imparting a forward curve to the cervical spine and reducing hyper-kyphosis of the upper thoracic spine comprises a frame having a transverse neck support projecting upwardly from first and second side portions defining a base of the frame. A first inflatable bladder portion is coupled to the neck support, the first inflatable bladder portion is configured to expand in an outward direction from the neck support a distance greater than the expansion of the first inflatable bladder portion in a transverse direction normal thereto. A second inflatable bladder portion is coupled to the neck support. The second inflatable bladder portion is configured to expand in an angular direction from the neck support. The second inflatable bladder portion is positioned generally below and to the side relative to the first inflatable bladder portion. A spacer is configured to be coupled between a portion of the frame and the second inflatable bladder portion to adjust the angulation of the second inflatable bladder portion during inflation. A pump system is provided for inflating the first and second inflatable bladder portions. Upon the first inflatable bladder portion expanding in the outward direction, the first inflatable bladder portion bears outwardly against the back of the user's neck. Upon expanding in the transverse direction, the first inflatable bladder portion applies an angular traction to the cervical spine. Upon the second inflatable bladder portion expanding in the angular direction, the second inflatable bladder portion bears angularly against the back of the user's upper thoracic region.

According to some implementations, additional features include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the second inflatable bladder portion during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the second inflatable bladder portion can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the second inflatable bladder portion to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

According to another implementation, a method of imparting a forward curve to the cervical spine and reducing hyper-kyphosis of the upper thoracic spine is provided. A traction device is secured to a user's head. The traction device comprises a support frame having a transverse neck support projecting upwardly from a base of the support frame and first and second inflatable bladder portions coupled to the neck support and a spacer coupled between a portion of the frame and the second inflatable bladder portion to adjust the angulation of the second inflatable bladder portion during inflation to provide lateral flexion traction. Securing the traction device to the user's head includes positioning the traction device such that the first inflatable bladder portion transverses the cervical spine, and such that the second inflatable bladder portion transverses the upper thoracic spine. The first inflatable bladder portion is expanded in a direction outward from the neck support and toward and substantially normal to the cervical spine to force the cervical spine to curve forwardly. The first inflatable bladder portion is expanded in a transverse direction to apply an angular traction to the cervical spine. The second inflatable bladder portion is expanded in a direction toward the upper thoracic spine to provide lateral flexion traction. In some embodiments, the spacer is rotated to adjust the angulation of the second inflatable bladder portion.

According to certain embodiments of the invention, devices, systems and methods are described that address compression of the occipital-cervical junction. In some embodiments, the devices, systems, and methods described herein apply pneumatic forces directly to the occiput.

In certain embodiments of the invention, devices, systems and methods are described that simultaneously address cervical lordotic curve loss/reversal (hypolordosis/kyphosis), the often accompanying posterior (−Z) translation (hyper-kyphosis) of the upper thoracic spine, and compression of the occipital-cervical junction. With the application of an air cell or pneumatic air chamber, the occipital-cervical junction is decompressed by the application of +Z/+Y force vectors.

In some embodiments, the devices, systems, and methods described herein apply pneumatic forces directly to the offending spinal apexes in opposing directions and to the occiput. With the simultaneous application of three separate air cells or pneumatic air chambers the cervical spine is locked and powerfully decompressed into its proper lordotic or curved configuration (<^>) with −Y+Z+Y force vectors while the hyper kyphotic area of the upper thoracic spine is simultaneously decompressed with a combination +Z/−Y force mid-vector and +Z/+Y force vectors are applied to the occiput to decompress the occipital-cervical junction. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the thoracic hyper-kyphosis is simultaneously reduced and the occipital-cervical junction is decompressed. In some embodiments, a two pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. In some embodiments, a three pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. In some embodiments, a complex multi vectored pneumatic air chamber can be used in place of three individual cells. In some embodiments, the devices, systems and methods described herein use the entire cervical spine as a first anchor point, the upper thoracic spine as a second point, and the occiput as a third point. The pneumatic air chambers can directly contact the cervical spine/occiput and the upper 25%-40% of the thoracic spine.

In certain embodiments, a traction device is provided. The device comprises a frame having a base and a neck support coupled to the base to support the neck of a user during use, a first inflatable bladder portion coupled to the neck support, a second inflatable bladder portion coupled to the neck support, and a third inflatable bladder portion coupled to the neck support. The first inflatable bladder portion is configured to expand in an outward direction from the neck support toward the neck of a user and to expand in a transverse direction substantially normal to the outward direction upon inflation. The second inflatable bladder portion is configured to expand in a first angular direction from the neck support and is positioned generally inferior to the first inflatable bladder portion. The third inflatable bladder portion is configured to expand in a second angular direction from the neck support and is positioned generally superior to the first inflatable bladder portion. Upon the first inflatable bladder portion expanding in the outward direction, the first inflatable bladder portion bears outwardly against the back of the neck of the user as the first inflatable bladder is inflated and forces the cervical spine to curve forwardly, and upon expanding in the transverse direction, the first inflatable bladder portion applies an angular traction to the cervical spine as the first inflatable bladder is inflated. Upon the second inflatable bladder portion expanding in the first angular direction, the second inflatable bladder portion bears angularly against the back of the upper thoracic region of the user as the second inflatable bladder is inflated and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine. Upon the third inflatable bladder portion expanding in the second angular direction, the third inflatable bladder portion bears angularly against the occiput of the user as the third inflatable bladder is inflated and forces the occipital-cervical junction to decompress.

In certain embodiments, a spacer is configured to be coupled between a portion of the frame and the second inflatable bladder portion to adjust the angulation of the second inflatable bladder portion during inflation. In certain embodiments, a spacer is configured to be coupled between a portion of the frame and the third inflatable bladder portion to adjust the angulation of the third inflatable bladder portion during inflation. In certain embodiments, a pump system is provided for inflating the first, second, and third inflatable bladder portions. In certain embodiments, a valve is positioned in communication with the pump system and the first inflatable bladder portion, the second inflatable bladder portion, and the third inflatable bladder portion, wherein the valve comprises varying lumen diameters that direct flow between the pump system and the first inflatable bladder portion, the second inflatable bladder portion, and the third inflatable bladder portion. In certain embodiments, upon inflation, the third inflatable bladder portion can impart 15° to 20° of forward head flexion to the occiput of the user.

According to some implementations, additional features include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the second inflatable bladder portion during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the second inflatable bladder portion can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the second inflatable bladder portion to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

According to some implementations, additional features include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the third inflatable bladder portion during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the third inflatable bladder portion can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the second inflatable bladder portion to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

In some embodiments, the devices, systems, and methods described herein apply pneumatic forces directly to the cervical spine and the occiput. With the simultaneous application of two separate air cells or pneumatic air chambers the cervical spine is locked and powerfully decompressed into its proper lordotic or curved configuration (<^>) with −Y+Z+Y force vectors the occipital-cervical junction is simultaneously decompressed with +Z/+Y force vectors. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the occipital-cervical junction is decompressed. In some embodiments, a two pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. In some embodiments, a complex multi vectored pneumatic air chamber can be used in place of two individual cells. In some embodiments, the devices, systems and methods described herein use the entire cervical spine as a first anchor point, and the occiput as a second point.

In certain embodiments, a traction device is provided. The traction device comprises a frame having a base and a neck support coupled to the base to support the neck of a user during use, a first inflatable bladder portion coupled to the neck support, and a second inflatable bladder portion coupled to the neck support. The first inflatable bladder portion is configured to expand in an outward direction from the neck support toward the neck of the user and in a transverse direction substantially normal to the outward direction upon inflation. The second inflatable bladder portion is configured to be positioned superior to the first inflatable bladder portion and is expandable in an angular direction from the neck support toward an occiput of the user upon inflation. Upon the first inflatable bladder portion expanding in the outward direction, the first inflatable bladder portion bears outwardly against the back of the neck of the user as the first inflatable bladder is inflated and forces the cervical spine to curve forwardly, and upon expanding in the transverse direction, the first inflatable bladder portion applies an angular traction to the cervical spine as the first inflatable bladder is inflated. Upon the second inflatable bladder portion expanding in the angular direction, the second inflatable bladder portion bears angularly against the occiput of the user as the second inflatable bladder is inflated and forces the occipital-cervical junction to decompress.

In certain embodiments, a spacer is configured to be coupled between a portion of the frame and the second inflatable bladder portion to adjust the angulation of the second inflatable bladder portion during inflation. In certain embodiments, a pump system is provided for selectively inflating and deflating one or more of the first and second inflatable bladder portions. In certain embodiments, a valve is positioned in communication with the pump system and the first and second inflatable bladder portions, wherein the valve comprises varying lumen diameters that direct flow between the pump system and the first and second inflatable bladder portions.

According to some implementations, additional features include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the second inflatable bladder portion during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the second inflatable bladder portion can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the second inflatable bladder portion to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

In certain embodiments, a method of imparting a forward curve to the cervical spine and reducing hyper-kyphosis of the upper thoracic spine is provided. The method comprises a step of securing a traction device to a head of a user. The traction device comprises a support frame having a transverse neck support projecting upwardly from a base of the support frame and first and second inflatable bladder portions coupled to the neck support. Securing the traction device to the head comprises positioning the traction device such that the first inflatable bladder portion transverses the cervical spine, and such that the second inflatable bladder portion transverses an occiput of the user. The method further comprises a step of expanding the first inflatable bladder portion in a direction outward from the neck support and toward and substantially normal to the cervical spine to force the cervical spine to curve forwardly. The method also comprises a step of expanding the first inflatable bladder portion in a transverse direction to apply an angular traction to the cervical spine. The method further comprises a step of expanding the second inflatable bladder portion in a direction toward the occiput to apply an angular traction to the occipital-cervical junction.

In some embodiments, the method further comprising a step of alternately inflating and deflating the first and second bladder portions. In some embodiments, the method further comprises a step of repeating inflation and deflation of the first and second bladder portions. In some embodiments, the second inflatable bladder portion has a semi-ellipsoidal configuration upon inflation. In some embodiments, the traction device comprises a third inflatable bladder portion coupled to the neck support. In some embodiments, securing the traction device to the head comprises positioning the traction device such that the third inflatable bladder portion transverses the upper thoracic spine. In some embodiments, the method further comprises a step of inflating the third bladder portion in a direction toward the upper thoracic spine to force the thoracic spine to decompress and reduce hyper-kyphosis of the upper thoracic spine. In some embodiments, the traction device comprises a valve positioned in communication with a pump system and the first inflatable bladder portion, the second inflatable bladder portion, and the third inflatable bladder portion. In some embodiments, the method further comprises a step of directing flow from the pump system through the valve to the first inflatable bladder portion, the second inflatable bladder portion, and the third inflatable bladder portion.

In some embodiments, the devices, systems, and methods described herein apply pneumatic forces directly to the thoracic spine and to the occiput. With the simultaneous application of two separate air cells or pneumatic air chambers, the hyper kyphotic area of the upper thoracic spine is simultaneously decompressed with a combination +Z/−Y force mid-vector and the occipital-cervical junction is decompressed with +Z/+Y force vectors. The thoracic hyper-kyphosis is simultaneously reduced and the occipital-cervical junction is decompressed. In some embodiments, the simultaneous application of two separate air cells or pneumatic air chambers, to the thoracic spine and the occiput can impart linear traction. In some embodiments, a two pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. In some embodiments, a complex multi vectored pneumatic air chamber can be used in place of two individual cells. In some embodiments, the devices, systems and methods described herein use the upper thoracic spine as a first anchoring point and the occiput as a second point. The pneumatic air chambers can directly contact the cervical spine/occiput and the upper 25%-40% of the thoracic spine.

In certain embodiments, a traction device is provided. The traction device comprises a frame having a base and a neck support coupled to the base to support the neck of a user during use, a first inflatable bladder portion coupled to the neck support, and a second inflatable bladder portion coupled to the neck support. The first inflatable bladder portion is configured to expand a first angular direction from the neck support. The second inflatable bladder portion is configured to be positioned superior to the first inflatable bladder portion and is expandable in a second angular direction from the neck support toward an occiput of the user upon inflation. Upon the first inflatable bladder portion expanding in the first angular direction, the first inflatable bladder portion bears angularly against the back of the upper thoracic region of the user as the second inflatable bladder is inflated and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine. Upon the second inflatable bladder portion expanding in the angular direction, the second inflatable bladder portion bears angularly against the occiput of the user as the second inflatable bladder is inflated and forces the occipital-cervical junction to decompress.

In certain embodiments, a spacer is configured to be coupled between a portion of the frame and the second inflatable bladder portion to adjust the angulation of the second inflatable bladder portion during inflation. In certain embodiments, a pump system is provided for selectively inflating and deflating one or more of the first and second inflatable bladder portions. In certain embodiments, a valve is positioned in communication with the pump system and the first and second inflatable bladder portions, wherein the valve comprises varying lumen diameters that direct flow between the pump system and the first and second inflatable bladder portions.

According to some implementations, additional features include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the first inflatable bladder portion during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the first inflatable bladder portion can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the second inflatable bladder portion to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

According to some implementations, additional features include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the second inflatable bladder portion during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the second inflatable bladder portion can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the second inflatable bladder portion to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

In certain embodiments, a traction device is provided. The traction device comprises a frame having a base and a neck support coupled to the base to support the neck of a user during use and an inflatable bladder portion coupled to the neck support. The inflatable bladder portion is configured to expand in an angular direction from the neck support. Upon the inflatable bladder portion expanding in the angular direction, the inflatable bladder portion bears angularly against the back of the upper thoracic region and the mid thoracic region of the user as the inflatable bladder is inflated and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine and the mid thoracic spine.

In certain embodiments, the inflatable bladder portion is a first inflatable bladder portion and the angular direction is a first angular direction. In certain embodiments, the traction device further comprises a second inflatable bladder portion coupled to the neck support, and the second inflatable bladder portion bladder portion is expandable in a second angular direction from the neck support toward a occiput of the user upon inflation. In certain embodiments, upon the second inflatable bladder portion expanding in the second angular direction, the second inflatable bladder portion bears angularly against the occiput of the user as the second inflatable bladder is inflated and forces the occipital-cervical junction to decompress the occipital-cervical junction. In certain embodiments, the traction device further comprises a third inflatable bladder portion coupled to the neck support, and the third inflatable bladder portion is configured to expand in an outward direction from the neck support toward the neck of the user and in a transverse direction substantially normal to the outward direction upon inflation. In certain embodiments, upon the third inflatable bladder portion expanding in the outward direction, the third inflatable bladder portion bears outwardly against the back of the neck of the user as the third inflatable bladder is inflated and forces the cervical spine to curve forwardly, and upon expanding in the transverse direction, the third inflatable bladder portion applies an angular traction to the cervical spine as the third inflatable bladder is inflated.

In certain embodiments, the inflatable bladder portion is a first inflatable bladder portion, and the traction device further comprises a second inflatable bladder portion coupled to the neck support. In certain embodiments, the second inflatable bladder portion is configured to expand in an outward direction from the neck support toward the neck of the user and in a transverse direction substantially normal to the outward direction upon inflation. In certain embodiments, upon the second inflatable bladder portion expanding in the outward direction, the second inflatable bladder portion bears outwardly against the back of the neck of the user as the second inflatable bladder is inflated and forces the cervical spine to curve forwardly, and upon expanding in the transverse direction, the second inflatable bladder portion applies an angular traction to the cervical spine as the second inflatable bladder is inflated.

In certain embodiments, a spacer is configured to be coupled between a portion of the frame and the inflatable bladder portion to adjust the angulation of the inflatable bladder portion during inflation. In certain embodiments, a pump system is provided for selectively inflating and deflating the inflatable bladder portion. In certain embodiments, a valve is positioned in communication with the pump system and the inflatable bladder portion, wherein the valve comprises varying lumen diameters that direct flow between the pump system and the inflatable bladder portion.

According to some implementations, additional features include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the inflatable bladder portion during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the inflatable bladder portion can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the inflatable bladder portion to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

These and other objects and advantages of the present disclosure will become readily apparent from the following detailed description taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of one embodiment of a decompression and traction system.

FIG. 2 is a perspective view of a portion of the system shown in FIG. 1.

FIG. 3 is a top view of a portion of the system shown in FIG. 1.

FIG. 4 is a side view of a portion of the system shown in FIG. 1.

FIG. 5 is a cross-sectional side view of a portion of the system shown in FIG. 1.

FIG. 6 is a perspective view of a valve component shown in the cross-sectional side view of FIG. 5.

FIG. 7 is a perspective view of a portion of the system shown in FIG. 1, showing a second inflatable bladder in an unassembled configuration.

FIG. 8 is a schematic view of another embodiment of a decompression and traction system, showing mobile pneumatic air chambers comprising a first inflatable bladder being pivotably adjustable and showing a spacer component configured to be selectively coupled to the frame to adjust a position of a second inflatable bladder.

FIG. 9 is a perspective view of the spacer component shown in FIG. 8.

FIGS. 10A-F are illustrative views of a patient's spine in multiple configurations, including some embodiments of decompression and traction systems in use in deflated and inflated configurations.

FIG. 11 is a schematic top view of a patient positioned on another embodiment of a decompression and traction system, showing pneumatic air chambers comprising first and second inflatable bladders and an adjustable spacer component configured to be selectively coupled to the frame to adjust a position of the second inflatable bladder, in the shown configuration the spacer component adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane.

FIG. 12 is a schematic top view of a patient and the embodiment of FIG. 11, showing a configuration wherein the spacer component is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force on one side of the patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction.

FIG. 13 is a bottom view of the embodiment of FIG. 11, in the shown configuration the spacer component adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane.

FIG. 14 is a bottom view of the embodiment of FIG. 11, showing a configuration wherein the spacer component is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force to a patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction.

FIG. 15 is a perspective view of one embodiment of a decompression and traction system.

FIG. 16 is a perspective view of a portion of the system shown in FIG. 15.

FIG. 17 is a top view of a portion of the system shown in FIG. 15.

FIG. 18 is a side view of a portion of the system shown in FIG. 15.

FIG. 19 is a cross-sectional side view of a portion of the system shown in FIG. 15.

FIG. 20 is a perspective view of a valve component shown in the cross-sectional side view of FIG. 19.

FIG. 21 is a perspective view of a portion of the system shown in FIG. 15, showing a third inflatable bladder in an unassembled configuration.

FIG. 22 is a schematic view of another embodiment of a decompression and traction system, showing mobile pneumatic air chambers comprising a first inflatable bladder being pivotably adjustable, showing a spacer component configured to be selectively coupled to the frame to adjust a position of a second inflatable bladder, and showing a spacer component configured to be selectively coupled to the frame to adjust a position of a third inflatable bladder.

FIGS. 23A-B are illustrative views of a patient's spine including embodiments of decompression and traction systems in use in inflated configurations.

FIG. 24 is a schematic top view of a patient positioned on another embodiment of a decompression and traction system, showing pneumatic air chambers comprising first, second, and third inflatable bladders, a first adjustable spacer component configured to be selectively coupled to the frame to adjust a position of the second inflatable bladder, wherein in the shown configuration the spacer component adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane, and a second adjustable spacer component configured to be selectively coupled to the frame to adjust a position of the third inflatable bladder, wherein in the shown configuration the spacer component adjusts the position of the third inflatable bladder to provide an even distribution of force generally along a force vector in the +Y and +Z plane

FIG. 25 is a schematic top view of a patient and the embodiment of FIG. 24, showing a configuration wherein the first spacer component is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force on one side of the patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction, and wherein the second spacer component is moved to adjust the position of the third inflatable bladder to provide an uneven distribution of force on one side of the patient in that a force vector is directed, for example, in a +Y, +Z, and −X direction.

FIG. 26 is a bottom view of the embodiment of FIG. 24, in the shown configuration the first spacer component adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane and the second spacer component adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the +Y and +Z plane.

FIG. 27 is a bottom view of the embodiment of FIG. 24, showing a configuration wherein the first spacer component is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force to a patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction and the second spacer component is moved to adjust the position of the third inflatable bladder to provide an uneven distribution of force to a patient in that a force vector is directed, for example, in a +Y, +Z, and −X direction.

FIG. 28 is a perspective view of one embodiment of a decompression and traction system.

FIG. 29 is a perspective view of one embodiment of a decompression and traction system.

FIG. 30 is an illustrative view of a patient's spine including an embodiment of a decompression and traction systems in use in an inflated configuration.

DETAILED DESCRIPTION

According to some preferred embodiments, the devices, systems and methods described herein relate to a decompression and traction system for imparting the desired lordotic shape into the cervical region of the spine and counteracting hyper-kyphosis of the area of the upper thoracic spine. Some systems can be used to work the spine and surrounding tissue to promote fluid and cellular exchange in and around the intervertebral discs.

In some embodiments, the device comprises a frame, a first substantially ellipsoidal inflatable bladder transversely in a neck support cradle carried by the frame, a second inflatable bladder supported on the neck support cradle carried by the frame and configured to provide a force vector against the upper thoracic spine when inflated, one or more restraining straps for securing the device to the user's head such that the first and second bladders are disposed against the back of the neck under a stress point in the cervical spine and against the hyper-kyphotic upper thoracic spine, respectively. Controlled inflation of the bladders by the user by a hand-held pump causes a controlled lifting and a stretching of the cervical and thoracic spine. As the first bladder is inflated, the configuration of the first bladder causes the first bladder to expand vertically and, to a lesser extent, transversely. The vertical expansion lifts the spine, creating a spinal apex while the transverse expansion of the bladder applies an angular traction to the neck on both sides of the apex. As the second bladder is inflated, preferably simultaneously, the configuration of the second bladder causes the second bladder to expand vertically and transversely. The vertical and transverse expansion lifts the spine and applies an angular traction to the thoracic region.

By controlling the inflation of the bladders, the user can control the lifting and stretching of the spine and incrementally increase the magnitude of spinal arc and decompression of the cervical and thoracic regions to his or her own tolerance. As the bladders are repetitively inflated to the tolerance of the user and deflated, the cervical spine is alternatively and actively forced from a lesser arc to a greater or hyper-lordotic arc and the hyper-kyphotic arc of the upper thoracic spine is simultaneously reduced and decompressed, thereby promoting nutrient transport to the intervertebral discs while simultaneously increasing the cervical lordotic arc and decreasing the thoracic hyper-kyphosis. These decompression and traction systems and related methods are described in greater detail below.

Referring now to the drawings, as shown in FIGS. 1-5, according to one embodiment, a traction device 110 comprises a frame 112, openings or slots 114 configured to receive one or more straps to restrain the forehead and/or chin of a user, a first inflatable air bladder 116, a second inflatable air bladder 118, and an air pump assembly 120.

The frame 112 is preferably molded of a durable plastic material in a tubular configuration so as to define a pair of side members 122 and 124 curved and meeting at an apex 126, and a transverse neck support 128. The frame side members 122 and 124 preferably form a stable base. The neck support 128 preferably comprises vertically extending portions 130 and 132 which project upwardly from the side members 122 and 124 respectively and project inwardly to define inwardly directed raised lateral portions 134 and 136. A neck cradle 138 extends transversely between portions 134 and 136, spanning frame side members 122 and 124. In some embodiments, the frame can be provided with side members that are not connected at an apex 126, such as in some embodiments where side members are shorter.

The first and second air bladders 116 and 118 are preferably configured for inflation and simultaneous application of force to the cervical and thoracic spine, when the patient is in a treatment position, to decompressed the spine into its proper lordotic or curved configuration (<^>) with −Y+Z+Y force vectors being applied to the cervical spine while the hyper-kyphotic area of the upper thoracic spine is simultaneously decompressed with a combination +Z/−Y force mid-vector. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the thoracic hyper-kyphosis is simultaneously reduced. In some embodiments, the devices, systems and methods described herein use the entire cervical spine including the occiput (base of skull) as the first anchor point and the upper thoracic spine as the second point. The pneumatic air chambers can directly contact the cervical spine/occiput and the upper 25%-40% of the thoracic spine. The first and second inflatable bladders 116, 118, are described in more detail below.

To provide selective inflation and deflation of the first and second inflatable bladders 116, 118, a flexible air line 140 of the air pump assembly 120 communicates the interior of the first and second inflatable bladders 116, 118 with a hand-operated air pump 142. In other embodiments an automated pump can be used. A pressure relief valve 144 is preferably disposed between the air line 140 and pump 142. Air line 140 preferably extends from the relief valve 144 through an opening in the neck support 128 and communicates with the first and second inflatable bladders 116, 118. In some embodiments, the air can be communicated through openings formed in the underside or ends of the bladders. In some embodiments, a valve 146, such as a multi-directional metering valve, shown in FIGS. 5 and 6 for example, can be coupled with the air line 140 and can direct air to the first and second inflatable bladders 116, 118. In some embodiments the valve 146 comprises different lumen diameters to vary the air flow directed to the opposing traction pneumatic air chambers of the first and second inflatable bladders 116, 118. Different valve components can be used to adjust the amount or flow of air to the respective pneumatic air chambers. While air is an example fluid used in the pneumatic decompression described herein, other suitable fluids can be used to increase or decrease the volume of the bladders, including using liquids in some embodiments. In some embodiments, a two pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. In some embodiments, a single complex multi-vectored cell or bladder can be used in place of two individual cells.

According to one embodiment, by way of example, a frame 112 of a traction device 110 defines a spacing of about nine inches between the curved side members 122 and 124 at a wide portion with the side members coming together at the apex 126 of the frame. The frame 112 is preferably between about 11 to 17 inches in length in some embodiments. The frame 112 preferably elevates the neck support 128 about 0.5 to about 1.5 inches above the floor or surface. In such a configuration, the frame 112 preferably bears against the floor or surface during use and reduces the tendency of the frame to twist about its transverse axis. The cradle 138 in neck support 128 preferably tapers from an elevation of about 3 inches above the floor proximate side members 122 and 124 to a central elevation of about 2.5 inches.

The first expandable bladder 116 is preferably coupled to and carried by the neck support 128 in the cradle 138 defined therein. The first expandable bladder 116 is preferably secured in place as will be described further herein. The lateral portions 134 and 136 of neck support 128 are preferably provided with oppositely facing recesses formed therein adjacent the lateral ends of cradle 138 for receiving the extended ends of the first expandable bladder 116 to facilitate retention and alignment of the bladder on the cradle 138.

According to some embodiments, the upper portion of the first expandable bladder 116 is of a generally semi-ellipsoidal configuration having relatively pointed ends similar to the upper half of a football bladder. In one preferred bladder configuration, the underside of the first expandable bladder 116 is formed with undercut portions so as to define a central depending portion. At least a portion of the cradle is preferably configured to receive the underside of the first expandable bladder 116. Preferably, the first expandable bladder 116, when inflated, will expand upwardly from the cradle 138 to a slightly greater extent than in a transverse direction. Additionally, in some embodiments, provision of the depending portion on the underside of the bladder provides a cushioning effect under the apex of the expanded bladder which bears against the user's neck, making the device more comfortable for the user. Thus, as the bladder is inflated under and against the user's neck, it expands vertically and transversely, lifting the spine to create a spinal apex and applying an angular traction to the neck on both sides of the spinal apex. The amount of traction exerted in the vertical direction, however, will be somewhat greater than that exerted longitudinally to obtain the vertical lift necessary to restore the normal lordotic shape to the cervical region of the spine without overly tractioning the neck longitudinally.

In some embodiments, the first inflatable bladder 116 is constructed of an expandable material such as neoprene rubber, defines a length of between about 8 to 10 inches, a height of about 3 to 4 inches in an uninflated state, and depending on the configuration of the bladder a transverse width of about 3 inches. In some embodiments, the bladder 116 is constructed of a material that resists expansion. In some embodiments, the bladder 116 is constructed of a heat-sealable urethane with 200 Denier nylon. The bladder 116 can comprise a cover of any suitable material, including, for example, a neoprene material. The semi-ellipsoidal upper portion of the first inflatable bladder 116, when inflated, defines a transverse arc of about 4 inches in length about the center of the bladder. It is to be understood that these dimensions are by way of example only and can be varied, as can the configuration of the frame, straps, and first and second bladders without departing from the spirit and scope of the invention. For example, in some embodiments the bladder 116 can have a length of between about 6 to 9 inches, a height of about 2 to 3 inches in a deflated state, a height of about 3 to 4 inches in an inflated state. In some embodiments a deflated circumference of the bladder is about 4 inches and an inflated circumference of the bladder is between about 7 and 8 inches. In an inflated configuration, the bladder 116 can be taller than it is wide, for example, it can be approximately 4 inches tall and approximately 3 inches wide when inflated in some embodiments.

The second expandable bladder 118 is coupled to and carried by the neck support 128. The second expandable bladder 118 is preferably adjustable in some embodiments to accommodate patient anatomy and align with desired force vector directions as will be described further herein. The lateral portions 134 and 136 of neck support 128 are preferably configured with recesses formed therein for receiving the extended ends 148, shown in FIG. 7, of the second expandable bladder 118 to facilitate retention and alignment of the bladder on the neck support 128.

According to some embodiments, the second expandable bladder 118 is of a generally semi-ellipsoidal configuration having a relatively curved portion upon inflation for engaging a portion of the thoracic spine. Preferably, the second expandable bladder 118, when inflated, will expand about the same amount transversely and upwardly from the neck support 128. In some embodiments, the second expandable bladder 118 when inflated expands more transversely than upwardly. In some embodiments, the second expandable bladder 118 when inflated expands more upwardly than transversely. Thus, as the second expandable bladder 118 is inflated under and against the user's thoracic spine, it expands transversely and vertically, lifting the spine to counter hyper-kyphosis and applying an angular traction to the thoracic spine. The amount of traction exerted in the longitudinal direction, preferably, will be similar to the amount of lift exerted vertically to obtain the necessary decompression and lift to restore the normal shape to the thoracic region of the spine.

In some embodiments, the second inflatable bladder 118 is constructed of an expandable material such as neoprene rubber, defines a length of between about 8 to 10 inches, a height of about 3 to 4 inches in an uninflated state, and depending on the configuration of the bladder a transverse width of about 3 inches. In some embodiments, the bladder 118 is constructed of a material that resists expansion. In some embodiments, the bladder 118 is constructed of a heat-sealable urethane with 200 Denier nylon. The bladder 118 can comprise a cover of any suitable material, including, for example, a neoprene material. The second inflatable bladder 118, when inflated, defines a transverse arc of about 4 inches in length about the center of the bladder. It is to be understood that these dimensions are by way of example only and can be varied without departing from the spirit and scope of the invention. For example, in some embodiments the bladder 118 can have a length of about 9 inches where it is coupled to the frame, a length of between about 6 and 7 inches where the bladder 118 contacts the patient. The bladder 118 can have a height of about 3 to 4 inches. The bladder 118 can have a circumference of about 6 to 7 inches.

In some embodiments the bladders preferably have a finite shape and expand while being filled until the bladders reach the finite shape. Once the bladder has been filled to the finite shape, the pressure release valve of the pump assembly allows for gas or fluid to escape from the system to maintain a desired pressure within the bladder. The pressure release valve is preferably an automatic pressure release valve. The system preferably also comprises a manual release valve, such as a push button release valve. The desired pressure is preferably held at a proven clinical level. In some embodiments the pressure release valve is configured to maintain a pressure of about 8 psi. At a pressure of about 8 psi the system preferably provides over 50 pounds of tractional force. In some embodiments the tractional force preferably is between about 50 and 60 pounds of tractional force.

While the above described bladder configurations are preferred, it is to be understood that other configurations of expandable bladders could be employed in the present invention, either with or without an expansion controlling casing to provide the desired lifting and traction of the user's neck and spine. Moreover, in some embodiments, mechanically expandable components can be used in place of the first and second bladders. Mechanically expandable components can be coupled to the frame and selectively expanded to apply force vectors to the cervical and thoracic spine in a manner similar to those produced by the expandable bladders as described herein. For example, in some embodiments an expanding mechanical component within a cushioned cover can be selectively actuated to provide the desired force distribution.

In some embodiments, one or more of the first and second expandable bladders 116, 118 are of a tubular configuration and are disposed in a non-expandable casing, preferably constructed of a vinyl or other suitable material. The casing is preferably formed in the above described generally ellipsoidal configurations. As the tubular bladder expands upon inflation, the expansion is limited by the configuration of the casing to provide the desired increase in the vertical and transverse directions.

In some embodiments, as shown in FIG. 8, the first expandable bladder 116 is preferably rotatably secured to the neck support 128. The first expandable bladder 116 can be tilted in a forward position, a backward position, or maintained in a central position. In some embodiments, the bladder can be locked into a desired position. Providing a rotatable first expandable bladder 116 preferably provides mobility for the pneumatic air chamber to comfortably accommodate various spinal configurations. In some embodiments, the second expandable bladder 118 can be rotatably secured to the neck support 128.

In some embodiments, as shown in FIGS. 8 and 9, a spacer component 150 is preferably configured to be selectively coupled to the frame 112 to adjust a position of a second inflatable bladder 118. The spacer component can be attached to the frame and can allow clinicians and users to increase the negative Y directional component of the lower pneumatic air chamber. In one embodiment, the spacer component comprises an pneumatic air chamber or bladder engaging face 152, a notched connector portion 154 and opposing side portions 156. Other spacer configurations can be used to modify the directional component of the second inflatable bladder 118.

FIGS. 10A-F are illustrative views of a patient's spine in multiple configurations, including some embodiments of decompression and traction systems in use in deflated and inflated configurations. FIG. 10A shows a patient with cervical curve loss, forward head carriage, and disc compression. FIG. 10B shows a patient with normal spinal curves. FIGS. 10C and 10D show a patient and one embodiment of a decompression system 110 having a chin and forehead restraint, wherein the views show the decompression system 110 in a deflated configuration and an inflated configuration, respectively. FIGS. 10E and 10F show a patient and another embodiment of a decompression system 110 having a forehead restraint, wherein the views show the decompression system 110 in a deflated configuration and an inflated configuration, respectively.

As shown in FIGS. 10C-F, restraint straps 158 and/or 160 can be secured at the ends thereof to one or more of slots 114. Straps can be passed under the user's chin and over the user's forehead in some embodiments. In other embodiments, a strap can be passed over the user's forehead only. The straps can be secured and fastened in any suitable manner. For example, interlocking hook and loop type fasteners, snaps, buckles or other fasteners can be used. According to some embodiments, the traction device 110 can be easily and securely affixed to the user's head with a strap configuration such that with the user lying flat on his or her back on a horizontal surface, the frame 112 rests on the surface and the neck support 128 is disposed under the user's neck and tapered ends 162 of the frame side members 122, 124 are substantially adjacent the user's shoulders and generally near the upper thoracic region. The tightness of the securement of the device 110 to the user's head can be readily adjusted as needed by the securement straps 158, 160.

In some embodiments, the system preferably comprises a frame made of virgin acrylonitrile butadiene styrene (ABS) plastic material. ABS is an engineering thermoplastic that is advantageous due to its strength, toughness, chemical resistance, and ability to maintain necessary stiffness. The expandable pneumatic air chambers are preferably made of heat-sealable urethane with 200 Denier nylon. The expandable pneumatic air chambers preferably have a neoprene cover. The facial straps are preferably made of a durable and waterproof neoprene material. The hand pump and tubing are preferably made of rubber/plastic. Other embodiments can include different materials.

According to some embodiments, the system is lightweight (for example, about 3 lbs), portable, easy to operate, requires no assembly, no weights, cables or ropes to set-up, comes with choice of ballistic nylon carrying case or educational box, instruction page and instructional DVD. In one embodiment, the device comprises a built-in frame, an expanding elliptical pneumatic air chamber (with neoprene cover) that creates radial tractional force and thoracic decompressive force, a patient-controlled pneumatic hand pump with a push button release and automatic safety valve connected to approximately 30 inches of tubing, and one dual action head restraint designed for patients who suffer with TMJ (does not aggravate temporomandibular joint), which comprises an adjustable forehead strap, and a removable chin strap (which is optional in some other embodiments).

Accordingly to one aspect disclosed herein, methods for pneumatic radial traction can restore the cervical and thoracic spine to the proper configuration. Pneumatic radial traction, also known in some embodiments as expanding ellipsoidal decompression (EED), is a process in which joints of the cervical spine are pneumatically tractioned and simultaneously aligned into the cervical spine's proper radial or curved configuration. A major clinical difference between some embodiments of a pneumatic radial traction device disclosed herein and some prior art devices is that the prior art devices flatten or reverse the proper cervical curve to attain joint separation. In some embodiments, a pneumatic radial traction device enhances or maintains the proper cervical curve while attaining over twice the joint separation as some prior art devices.

With reference to FIGS. 10A and 10B, in the upright position, the cervical “lordotic” curve is what allows the weight of the head (10-15 lbs.) to be directed toward the hard boney posterior articular surfaces of the neck rather than toward the softer anterior discs as in the compressed neck. Through modern healthcare imaging it can be seen that that loss of the normal forward cervical curve)(approx. 43° and the resulting anterior disc compression this causes, was a contributing factor in osteophyte formation (Wolff's Law), posterior disc bulging, disc herniation, disc degeneration, neck pain and loss in cervical range of motion.

With reference to FIGS. 10C to 10F, pneumatic radial traction separates and simultaneously aligns the spinal joints in a curved or radial configuration. In some embodiments, an elliptical pneumatic air chamber directs multi-vectored expansive forces from within the posterior spinal concavity (back of neck), vertically (+Z axis translation) and in both horizontal directions. The spine is simultaneously tractioned in three main directions. The radial configuration created by these multi-vectored forces produces high level joint separation at the posterior, middle and anterior of the disc while forcefully enhancing the cervical spine's proper curve, rather than flattening or reversing the curve. Pneumatic radial traction is preferably achieved when the joints are separated by a vertical displacement greater than the horizontal displacement, however, displacement of equal height and width is also advantageous in some embodiments. An advantage of a pneumatic radial traction device is that it does not flatten or reverse the proper cervical curve while attaining joint separation. In some embodiments, the system provides a traction device with multiple fulcrums. For example, at least two fulcrums are provided to provide treatment to the cervical and thoracic spine of the patient.

As the head is stabilized in the cervical device, joints are actively tractioned in 3 main directions instead of one or two. The cervical spine is tractioned vertically along the +Z axis with a pneumatic force of over 58 lbs. This force expands into and against the posterior cervical concavity. Simultaneously the spine is tractioned horizontally in the two traditional directions (+Y and −Y) with a pneumatic force of over 40-lbs in each direction. These forces expand against the occiput and against the upper thoracic region. The combination of these simultaneously applied pneumatic forces produce radial traction. When fully inflated the elliptical pneumatic cell expands to a 7.5 inch radius, affecting the entire cervical spine. High level joint traction occurs at the posterior, center and anterior aspect of the vertebral bodies in a ratio coinciding with the discs' natural wedged spacing. While the pneumatic radial traction device separates the posterior of the joints to a magnitude typical of traditional traction, it separates the overall disc more than twice as much as linear traction.

With the simultaneous application of two separate pneumatic air chambers the cervical spine is decompressed into its proper lordotic or curved configuration (<^>) with −Y+Z+Y force vectors while the hyper kyphotic area of the upper thoracic spine is simultaneously decompressed with a combination +Z/−Y force mid-vector. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the thoracic hyper-kyphosis is simultaneously reduced.

Continuous expansion and contraction of the pneumatic air chambers can be employed to create alternating hydration and milking of the intervertebral discs, activating their sponge-like imbibition action. Holding the air pressure constant over a period of 15 to 20 minutes has the effect of simultaneously molding the spine into a curved or elliptical shape, decompressing discs and relaxing the dura, cord and nerve-roots in the cervical canal.

Embodiments described herein are preferably prescribed for patients with chronic neck pain due to a musculoskeletal or neurological impairment. The system applies radial tractional force to the cervical spine, enhancing the cervical lordotic curve while achieving high level joint separation at the anterior, center and posterior aspect of the vertebral bodies and discs in a ratio corresponding with their natural wedged spacing, reducing disc protrusions, compression and increasing range of motion. In some applications, devices advantageously decrease pain in chronic neck pain patients, decrease headaches and increase range of motion while reducing the necessity for chronic pain medication and neck surgery.

With continued reference to FIGS. 10A-10F, according to some embodiments in use, the traction device 110 rests on a horizontal surface such that the neck support 128 projects upwardly therefrom. The user lies on the device in a prone position such that the back of the neck rests on the deflated first expandable bladder 116 carried in the cradle 138 of the neck support 128. The deflated second expandable bladder 118 is positioned between the neck support 128 and portions of the thoracic spine of the user. The chin and/or forehead restraining restraint straps are respectively extended under the user's chin and/or about the user's forehead and secured, thereby affixing the traction device 110 to the user such that the neck and cervical spine extend over the neck support and first expandable bladder 116 and the thoracic spine is adjacent the second expandable bladder 118. According to one preferred embodiment, the outward extension of the neck support 128 is relatively slight so that when the bladder is in the deflated position with the forehead and chin restraints secured, very little or no force is exerted on the neck by the neck support. This is achieved by elevating the neck support 128 above the frame such that the neck cradle 138 formed therein is about 2 to 3 inches above the floor or other horizontal surface on which the device 110 is used. The first expandable bladder 116 is sized such that upon full inflation, the apex of the curved upper surface of the bladder will extend about 5 inches above the floor or surface. The second expandable bladder 118 is sized such that upon full inflation, a surface of the second expandable bladder engaging the thoracic spine will extend toward the thoracic spine about 2 to 3 inches in the −Y/+Z direction.

In some embodiments, as the user slowly inflates the first and second inflatable bladders 116, 118 using the air pump 142, the first inflatable bladder 116 expands upwardly and, to a lesser extent, transversely, thereby forcing the cervical spine forwardly creating a spinal apex while concurrently stretching the spine angularly along both sides of the formed spinal apex. The second inflatable bladder 118 expands transversely in the −Y direction, thereby forcing the thoracic spine forwardly to offset the effects of hyper-khyphosis. The user then continues to inflate the first and second bladders 116 and 118 until his or her individual tolerance level is reached. The bladders are then deflated by use of the one way valve 144. The process is preferably repeated several times, slowly increasing the spinal arc in the cervical region and placing pressure on the thoracic region as the level of tolerance increases. In addition, the first and second bladders 116 and 118 can be held in an inflated state at or slightly below the level of tolerance for varying periods of time up to ten to twenty minutes. Through such repetition, the cervical spine, thoracic spine and surrounding tissue receive a workout promoting cellular exchange in and around the intervertebral disc and a forward curve is reinstated into the cervical spine while achieving proper spine configuration in the thoracic region. FIGS. 10A-10F illustrate the effects of the traction and exercise devices 110 of some embodiments on the cervical and thoracic spine.

With reference to FIGS. 11-14, an adjustable spacer component 150 can be provided in some implementations of a traction system 110 to provide for lateral flexion traction. For example, FIG. 11 is a schematic top view of a patient positioned on another embodiment of a decompression and traction system, showing pneumatic air chambers comprising first and second inflatable bladders 116, 118 and an adjustable wedge-shaped spacer component 150 configured to be selectively coupled to the frame to adjust a position of the second inflatable bladder, in the shown configuration the spacer component is in a vertical orientation and adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane without providing any lateral flexion traction to the patient.

FIG. 12 shows a configuration wherein the spacer component is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force on one side of the patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction. For example, the spacer component is turned or rotated to a horizontal position, whereby the wedge shape of the spacer contacts the second inflatable bladder and causes the bladder to deflect in one lateral direction more than another lateral direction. As shown, the spacer is placed in right horizontal position and causes more deflection on the right side of the patient. In other configurations, the spacer can be positioned in a left horizontal position to cause more deflection on the left side of the patient. Based on the positioning of the spacer, the second bladder can expand in an angular direction. Turning the spacer component sideways creates lateral flexion traction by forcing the shoulder/trapezius down while the head is held in traction.

FIG. 13 is a bottom view of the embodiment of FIG. 11 and shows the spacer component in a vertical position that adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane, but does not direct force laterally in a −X or +X direction. FIG. 14 is a bottom view of the embodiment of FIG. 11, showing a configuration wherein the spacer component is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force to a patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction as described in connection with FIG. 12. The lower linear displacement pneumatic air chamber is adjusted with a rotating wedge shaped spacer component, allowing clinicians to increase the angle and force of the mid (−Y)/(+Z) vector of this pneumatic air chamber. When adjusted to the right or left horizontal position, the rotating wedge allows clinicians to unilaterally increase and rotate the (−Y) directional component on either the right or left side (+/−X) of the upper thoracic region, producing lateral flexion traction. The rotating wedge shaped spacer component can be removed in some implementations to accommodate extreme kyphotic thoracic spines.

In some embodiments, the device comprises a frame, a first substantially ellipsoidal inflatable bladder transversely in a neck support cradle carried by the frame, a second inflatable bladder supported on the neck support cradle carried by the frame and configured to provide a force vector against the upper thoracic spine when inflated, a third inflatable bladder supported on the neck support cradle carried by the frame and configured to provide a force vector against the occiput when inflated, one or more restraining straps for securing the device to the user's head such that the first and second bladders are disposed against the back of the neck under a stress point in the cervical spine and against the hyper-kyphotic upper thoracic spine, respectively. Controlled inflation of the bladders by the user by a hand-held pump causes a controlled lifting and a stretching of the cervical and thoracic spine and decompression of the occipital-cervical junction. As the first bladder is inflated, the configuration of the first bladder causes the first bladder to expand vertically and, to a lesser extent, transversely. The vertical expansion lifts the spine, creating a spinal apex while the transverse expansion of the bladder applies an angular traction to the neck on both sides of the apex. As the second bladder is inflated, preferably simultaneously, the configuration of the second bladder causes the second bladder to expand vertically and transversely. The vertical and transverse expansion lifts the spine and applies an angular traction to the thoracic region. As the third bladder is inflated, preferably simultaneously, the configuration of the third bladder causes the third bladder to expand vertically and transversely. The vertical and transverse expansion lifts the head and applies an angular traction to the occiput.

By controlling the inflation of the bladders, the user can control the lifting and stretching of the spine and incrementally increase the magnitude of spinal arc and decompression of the cervical region, thoracic region, and occipital-cervical junction to his or her own tolerance. As the bladders are repetitively inflated to the tolerance of the user and deflated, the cervical spine is alternatively and actively forced from a lesser arc to a greater or hyper-lordotic arc, the hyper-kyphotic arc of the upper thoracic spine is simultaneously reduced and decompressed, and the occipital-cervical junction is simultaneously decompressed, thereby promoting nutrient transport to the intervertebral discs while simultaneously increasing the cervical lordotic arc and decreasing the thoracic hyper-kyphosis. These decompression and traction systems and related methods are described in greater detail below.

Referring now to the drawings, as shown in FIGS. 15-19, according to one embodiment, a traction device 210 comprises the frame 112, openings or slots 114 configured to receive one or more straps to restrain the forehead and/or chin of a user, the first inflatable air bladder 116, the second inflatable air bladder 118, a third inflatable bladder 119, and an air pump assembly 120.

The frame 112 is preferably molded of a durable plastic material in a tubular configuration so as to define a pair of side members 122 and 124 curved and meeting at an apex 126, and a transverse neck support 128. The frame side members 122 and 124 preferably form a stable base. The neck support 128 preferably comprises vertically extending portions 130 and 132 which project upwardly from the side members 122 and 124 respectively and project inwardly to define inwardly directed raised lateral portions 134 and 136. A neck cradle 138 extends transversely between portions 134 and 136, spanning frame side members 122 and 124. In some embodiments, the frame can be provided with side members that are not connected at an apex 126, such as in some embodiments where side members are shorter.

The first, second, and third air bladders 116, 118, and 119 are preferably configured for inflation and simultaneous application of force to the cervical spine, the thoracic spine, and the occiput, when the patient is in a treatment position, to decompress the spine into its proper lordotic or curved configuration (<^>) with −Y+Z+Y force vectors being applied to the cervical spine while the hyper-kyphotic area of the upper thoracic spine is simultaneously decompressed with a combination +Z/−Y force mid-vector and +Z/+Y force vectors are applied to the occiput to decompress the occipital-cervical junction. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the thoracic hyper-kyphosis is simultaneously reduced. In some embodiments, the devices, systems and methods described herein use the entire cervical spine as a first anchor point, the upper thoracic spine as a second point, and the occiput as a third anchor point. The pneumatic air chambers can directly contact the cervical spine, the upper 25%-40% of the thoracic spine, and the occiput. The first, second, and third inflatable bladders 116, 118, and 119 are described in more detail below.

To provide selective inflation and deflation of the first, second, and third inflatable bladders 116, 118, and 119, a flexible air line 140 of the air pump assembly 120 communicates the interior of the first, second, and third inflatable bladders 116, 118, and 119 with a hand-operated air pump 142. In other embodiments an automated pump or electronic pump can be used. The electronic pump may be part of an electronic pump system. In certain embodiments, the electronic pump system can include a processor configured to execute one or more software applications that cause the electronic pump to fill one or more of the first, second, and third inflatable bladders 116, 118, and 119. In certain embodiments, the electronic pump can be configured to inflate one or more of the first, second, and third inflatable bladders 116, 118, and 119 to one or more predefined or user selected inflation amounts. For example, in some embodiments, the software applications allow for selective inflation of one or more of the first, second, and third inflatable bladders 116, 118, and 119 to low, medium, and/or high amounts of inflation. In certain embodiments, the electronic pump system can include a user interface that allows a user to select and/or control one or more settings of the pump. For example, the user interface can allow for a selection of one or more of the first, second, and third inflatable bladders 116, 118, and 119 for inflation. In some embodiments, the user interface can allow for a selection of one or more inflation amounts for each inflatable bladder. In certain embodiments, the user interface can be provided on the electronic pump. In some embodiments, the user interface can be provided on an external device.

A pressure relief valve 144 is preferably disposed between the air line 140 and pump 142. Air line 140 preferably extends from the relief valve 144 through an opening in the neck support 128 and communicates with the first and second inflatable bladders 116, 118. In some embodiments, the air can be communicated through openings formed in the underside or ends of the bladders. In some embodiments, a valve 246, such as a multi-directional metering valve, shown in FIGS. 19 and 20 for example, can be coupled with the air line 140 and can direct air to the first, second, and third inflatable bladders 116, 118, and 119. In some embodiments the valve 246 comprises different lumen diameters to vary the air flow directed to the opposing traction pneumatic air chambers of the first, second, and third inflatable bladders 116, 118, and 119. Different valve components can be used to adjust the amount or flow of air to the respective pneumatic air chambers. While air is an example fluid used in the pneumatic decompression described herein, other suitable fluids can be used to increase or decrease the volume of the bladders, including using liquids in some embodiments. In some embodiments, a two pump system or a three pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. For example, in some embodiments, a first pump can be employed to inflate the first inflatable bladder 116 and a second pump can be employed to inflate the second and third inflatable bladders 118 and 119. In some embodiments, a first pump can be employed to inflate the first and second inflatable bladders 116 and 118 and a second pump can be employed to inflate the third inflatable bladder 119. In some embodiments, a pump can be employed to inflate the first and third inflatable bladders 116 and 119 and a second pump can be employed to inflate the second inflatable bladder 118. In some embodiments, a single complex multi-vectored cell or bladder can be used in place of three individual cells. In some embodiments, a single complex multi-vectored cell or bladder can be used in place of two of three inflatable bladders 116, 118, and 119. For example, in some embodiments, a single complex multi-vectored cell or bladder can be used in place of the first and second inflatable bladders 116 and 118. In some embodiments, a single complex multi-vectored cell or bladder can be used in place of the first and third inflatable bladders 116 and 119.

According to one embodiment, by way of example, a frame 112 of a traction device 110 defines a spacing of about nine inches between the curved side members 122 and 124 at a wide portion with the side members coming together at the apex 126 of the frame. The frame 112 is preferably between about 11 to 17 inches in length in some embodiments. The frame 112 preferably elevates the neck support 128 about 0.5 to about 1.5 inches above the floor or surface. In such a configuration, the frame 112 preferably bears against the floor or surface during use and reduces the tendency of the frame to twist about its transverse axis. The cradle 138 in neck support 128 preferably tapers from an elevation of about 3 inches above the floor proximate side members 122 and 124 to a central elevation of about 2.5 inches.

The first expandable bladder 116 is preferably coupled to and carried by the neck support 128 in the cradle 138 defined therein. The first expandable bladder 116 is preferably secured in place as will be described further herein. The lateral portions 134 and 136 of neck support 128 are preferably provided with oppositely facing recesses formed therein adjacent the lateral ends of cradle 138 for receiving the extended ends of the first expandable bladder 116 to facilitate retention and alignment of the bladder on the cradle 138.

According to some embodiments, the upper portion of the first expandable bladder 116 is of a generally semi-ellipsoidal configuration having relatively pointed ends similar to the upper half of a football bladder. In one preferred bladder configuration, the underside of the first expandable bladder 116 is formed with undercut portions so as to define a central depending portion. At least a portion of the cradle is preferably configured to receive the underside of the first expandable bladder 116. Preferably, the first expandable bladder 116, when inflated, will expand upwardly from the cradle 138 to a slightly greater extent than in a transverse direction. Additionally, in some embodiments, provision of the depending portion on the underside of the bladder provides a cushioning effect under the apex of the expanded bladder which bears against the user's neck, making the device more comfortable for the user. Thus, as the bladder is inflated under and against the user's neck, it expands vertically and transversely, lifting the spine to create a spinal apex and applying an angular traction to the neck on both sides of the spinal apex. The amount of traction exerted in the vertical direction, however, will be somewhat greater than that exerted longitudinally to obtain the vertical lift necessary to restore the normal lordotic shape to the cervical region of the spine without overly tractioning the neck longitudinally.

In some embodiments, the first inflatable bladder 116 is constructed of an expandable material such as neoprene rubber, defines a length of between about 8 to 10 inches, a height of about 3 to 4 inches in an uninflated state, and depending on the configuration of the bladder a transverse width of about 3 inches. In some embodiments, the bladder 116 is constructed of a material that resists expansion. In some embodiments, the bladder 116 is constructed of a heat-sealable urethane with 200 Denier nylon. The bladder 116 can comprise a cover of any suitable material, including, for example, a neoprene material. The semi-ellipsoidal upper portion of the first inflatable bladder 116, when inflated, defines a transverse arc of about 4 inches in length about the center of the bladder. It is to be understood that these dimensions are by way of example only and can be varied, as can the configuration of the frame, straps, and first and second bladders without departing from the spirit and scope of the invention. For example, in some embodiments the bladder 116 can have a length of between about 6 to 9 inches, a height of about 2 to 3 inches in a deflated state, a height of about 3 to 4 inches in an inflated state. In some embodiments a deflated circumference of the bladder is about 4 inches and an inflated circumference of the bladder is between about 7 and 8 inches. In an inflated configuration, the bladder 116 can be taller than it is wide, for example, it can be approximately 4 inches tall and approximately 3 inches wide when inflated in some embodiments.

The second expandable bladder 118 is coupled to and carried by the neck support 128. The second expandable bladder 118 is preferably adjustable in some embodiments to accommodate patient anatomy and align with desired force vector directions as will be described further herein. The lateral portions 134 and 136 of neck support 128 are preferably configured with recesses formed therein for receiving the extended ends 148, for example, as described with respect to FIG. 7, of the second expandable bladder 118 to facilitate retention and alignment of the bladder on the neck support 128.

According to some embodiments, the second expandable bladder 118 is of a generally semi-ellipsoidal configuration having a relatively curved portion upon inflation for engaging a portion of the thoracic spine. Preferably, the second expandable bladder 118, when inflated, will expand about the same amount transversely and upwardly from the neck support 128. In some embodiments, the second expandable bladder 118 when inflated expands more transversely than upwardly. In some embodiments, the second expandable bladder 118 when inflated expands more upwardly than transversely. Thus, as the second expandable bladder 118 is inflated under and against the user's thoracic spine, it expands transversely and vertically, lifting the spine to counter hyper-kyphosis and applying an angular traction to the thoracic spine. The amount of traction exerted in the longitudinal direction, preferably, will be similar to the amount of lift exerted vertically to obtain the necessary decompression and lift to restore the normal shape to the thoracic region of the spine.

In some embodiments, the second inflatable bladder 118 is constructed of an expandable material such as neoprene rubber, defines a length of between about 8 to 10 inches, a height of about 3 to 4 inches in an uninflated state, and depending on the configuration of the bladder a transverse width of about 3 inches. In some embodiments, the bladder 118 is constructed of a material that resists expansion. In some embodiments, the bladder 118 is constructed of a heat-sealable urethane with 200 Denier nylon. The bladder 118 can comprise a cover of any suitable material, including, for example, a neoprene material. The second inflatable bladder 118, when inflated, defines a transverse arc of about 4 inches in length about the center of the bladder. It is to be understood that these dimensions are by way of example only and can be varied without departing from the spirit and scope of the invention. For example, in some embodiments the bladder 118 can have a length of about 9 inches where it is coupled to the frame, a length of between about 6 and 7 inches where the bladder 118 contacts the patient. The bladder 118 can have a height of about 3 to 4 inches. The bladder 118 can have a circumference of about 6 to 7 inches.

The third expandable bladder 119 is coupled to and carried by the neck support 128. The third expandable bladder 119 is preferably adjustable in some embodiments to accommodate patient anatomy and align with desired force vector directions as will be described further herein. The lateral portions 134 and 136 of neck support 128 are preferably configured with recesses formed therein for receiving the extended ends 149, shown in FIG. 21, of the third expandable bladder 119 to facilitate retention and alignment of the bladder on the neck support 128.

According to some embodiments, the third expandable bladder 119 is of a generally semi-ellipsoidal configuration having a relatively curved portion upon inflation for engaging a portion of the thoracic spine. Preferably, the third expandable bladder 119, when inflated, will expand about the same amount transversely and upwardly from the neck support 128. In some embodiments, the third expandable bladder 119 when inflated expands more transversely than upwardly. In some embodiments, the third expandable bladder 119 when inflated expands more upwardly than transversely. Thus, as the third expandable bladder 119 is inflated under and against the user's occiput, it expands transversely and vertically, lifting the occiput to apply an angular traction to the occiput. The amount of traction exerted in the longitudinal direction, preferably, will be similar to the amount of lift exerted vertically to decompress the occipital-cervical junction.

In some embodiments, the third inflatable bladder 119 is constructed of an expandable material such as neoprene rubber, defines a length of between about 8 to 10 inches, a height of about 3 to 4 inches in an uninflated state, and depending on the configuration of the bladder a transverse width of about 3 inches. In some embodiments, the bladder 119 is constructed of a material that resists expansion. In some embodiments, the bladder 119 is constructed of a heat-sealable urethane with 200 Denier nylon. The bladder 119 can comprise a cover of any suitable material, including, for example, a neoprene material. The third inflatable bladder 119, when inflated, defines a transverse arc of about 4 inches in length about the center of the bladder. It is to be understood that these dimensions are by way of example only and can be varied without departing from the spirit and scope of the invention. For example, in some embodiments the bladder 119 can have a length of about 9 inches where it is coupled to the frame, a length of between about 6 and 7 inches where the bladder 119 contacts the patient. The bladder 119 can have a height of about 3 to 4 inches. The bladder 119 can have a circumference of about 6 to 7 inches.

In some embodiments the bladders preferably have a finite shape and expand while being filled until the bladders reach the finite shape. Once the bladder has been filled to the finite shape, the pressure release valve of the pump assembly allows for gas or fluid to escape from the system to maintain a desired pressure within the bladder. The pressure release valve is preferably an automatic pressure release valve. The system preferably also comprises a manual release valve, such as a push button release valve. The desired pressure is preferably held at a proven clinical level. In some embodiments the pressure release valve is configured to maintain a pressure of about 8 psi. At a pressure of about 8 psi the system preferably provides over 50 pounds of tractional force. In some embodiments the tractional force preferably is between about 50 and 60 pounds of tractional force.

While the above described bladder configurations are preferred, it is to be understood that other configurations of expandable bladders could be employed in the present invention, either with or without an expansion controlling casing to provide the desired lifting and traction of the user's neck, spine, and head. Moreover, in some embodiments, mechanically expandable components can be used in place of the first, second, and/or third bladders. Mechanically expandable components can be coupled to the frame and selectively expanded to apply force vectors to the cervical and thoracic spine in a manner similar to those produced by the expandable bladders as described herein. For example, in some embodiments an expanding mechanical component within a cushioned cover can be selectively actuated to provide the desired force distribution.

In some embodiments, one or more of the first, second, and third expandable bladders 116, 118, and 119 are of a tubular configuration and are disposed in a non-expandable casing, preferably constructed of a vinyl or other suitable material. The casing is preferably formed in the above described generally ellipsoidal configurations. As the tubular bladder expands upon inflation, the expansion is limited by the configuration of the casing to provide the desired increase in the vertical and transverse directions.

In some embodiments, as shown in FIG. 22, the first expandable bladder 116 is preferably rotatably secured to the neck support 128. The first expandable bladder 116 can be tilted in a forward position, a backward position, or maintained in a central position. In some embodiments, the bladder can be locked into a desired position. Providing a rotatable first expandable bladder 116 preferably provides mobility for the pneumatic air chamber to comfortably accommodate various spinal configurations. In some embodiments, the second expandable bladder 118 can be rotatably secured to the neck support 128. In some embodiments, the third expandable bladder 119 can be rotatably secured to the neck support 128.

In some embodiments, as shown in FIG. 22, a first spacer component 150A is preferably configured to be selectively coupled to the frame 112 to adjust a position of a second inflatable bladder 118. The spacer component can be attached to the frame and can allow clinicians and users to increase the negative Y directional component of the lower pneumatic air chamber. A second spacer component 150B is preferably coupled to the frame 112 to adjust a position of the third inflatable bladder 119. The spacer component can be attached to the frame and can allow clinicians and users to increase the positive Y direction of the upper pneumatic air chamber. Each of the spacer components 150A and 150B can include the same or generally similar features as the spacer component 150 described with respect to FIGS. 8 and 9. For example, in one embodiment, each spacer component comprises an pneumatic air chamber or bladder engaging face 152, a notched connector portion 154 and opposing side portions 156. Other spacer configurations can be used to modify the directional component of the second inflatable bladder 118 and the third inflatable bladder 119.

FIGS. 23A and 23B show a patient and an embodiment of a decompression and traction system 210 having a forehead restraint, wherein the views show the decompression system 210 in an inflated configuration, respectively.

As shown in FIGS. 23A and 23B, restraint straps 158 and/or 160 can be secured at the ends thereof to one or more of slots 114. Straps can be passed under the user's chin and over the user's forehead in some embodiments. In other embodiments, a strap can be passed over the user's forehead only. The straps can be secured and fastened in any suitable manner. For example, interlocking hook and loop type fasteners, snaps, buckles or other fasteners can be used. According to some embodiments, the traction device 210 can be easily and securely affixed to the user's head with a strap configuration such that with the user lying flat on his or her back on a horizontal surface, the frame 112 rests on the surface and the neck support 128 is disposed under the user's neck and tapered ends 162 of the frame side members 122, 124 are substantially adjacent the user's shoulders and generally near the upper thoracic region. The tightness of the securement of the device 110 to the user's head can be readily adjusted as needed by the securement straps 158, 160.

In some embodiments, the system preferably comprises a frame made of virgin acrylonitrile butadiene styrene (ABS) plastic material. ABS is an engineering thermoplastic that is advantageous due to its strength, toughness, chemical resistance, and ability to maintain necessary stiffness. The expandable pneumatic air chambers are preferably made of heat-sealable urethane with 200 Denier nylon. The expandable pneumatic air chambers preferably have a neoprene cover. The facial straps are preferably made of a durable and waterproof neoprene material. The hand pump and tubing are preferably made of rubber/plastic. Other embodiments can include different materials.

According to some embodiments, the system is lightweight (for example, about 3 lbs), portable, easy to operate, requires no assembly, no weights, cables or ropes to set-up, comes with choice of ballistic nylon carrying case or educational box, instruction page and instructional DVD. In one embodiment, the device comprises a built-in frame, an expanding elliptical pneumatic air chamber (with neoprene cover) that creates radial tractional force and thoracic decompressive force, a patient-controlled pneumatic hand pump with a push button release and automatic safety valve connected to approximately 30 inches of tubing, and one dual action head restraint designed for patients who suffer with TMJ (does not aggravate temporomandibular joint), which comprises an adjustable forehead strap, and a removable chin strap (which is optional in some other embodiments).

Accordingly to one aspect disclosed herein, methods for pneumatic radial traction can restore the cervical and thoracic spine to the proper configuration. Pneumatic radial traction, also known in some embodiments as expanding ellipsoidal decompression (EED), is a process in which joints of the cervical spine are pneumatically tractioned and simultaneously aligned into the cervical spine's proper radial or curved configuration. A major clinical difference between some embodiments of a pneumatic radial traction device disclosed herein and some prior art devices is that the prior art devices flatten or reverse the proper cervical curve to attain joint separation. In some embodiments, a pneumatic radial traction device enhances or maintains the proper cervical curve while attaining over twice the joint separation as some prior art devices.

With reference to FIGS. 23A and 23B, pneumatic radial traction separates and simultaneously aligns the spinal joints in a curved or radial configuration. In some embodiments, an elliptical pneumatic air chamber directs multi-vectored expansive forces from within the posterior spinal concavity (back of neck), vertically (+Z axis translation) and in both horizontal directions. The spine is simultaneously tractioned in three main directions. The radial configuration created by these multi-vectored forces produces high level joint separation at the posterior, middle and anterior of the disc while forcefully enhancing the cervical spine's proper curve, rather than flattening or reversing the curve. Pneumatic radial traction is preferably achieved when the joints are separated by a vertical displacement greater than the horizontal displacement, however, displacement of equal height and width is also advantageous in some embodiments. An advantage of a pneumatic radial traction device is that it does not flatten or reverse the proper cervical curve while attaining joint separation. In some embodiments, the system provides a traction device with multiple fulcrums. For example, at least two fulcrums, and preferably three fulcrums, are provided to provide treatment to the cervical spine, thoracic spine, and occiputal-cervical junction of the patient.

As the head is stabilized in the cervical device, joints are actively tractioned in 3 main directions instead of one or two. The cervical spine is tractioned vertically along the +Z axis with a pneumatic force of over 58 lbs. This force expands into and against the posterior cervical concavity. Simultaneously the spine is tractioned horizontally in the two traditional directions (+Y and −Y) with a pneumatic force of over 40-lbs in each direction. These forces expand against the occiput and against the upper thoracic region. The combination of these simultaneously applied pneumatic forces produce radial traction. When fully inflated the elliptical pneumatic cell expands to a 7.5 inch radius, affecting the entire cervical spine. High level joint traction occurs at the posterior, center and anterior aspect of the vertebral bodies in a ratio coinciding with the discs' natural wedged spacing. While the pneumatic radial traction device separates the posterior of the joints to a magnitude typical of traditional traction, it separates the overall disc more than twice as much as linear traction.

With the simultaneous application of three separate pneumatic air chambers the cervical spine is decompressed into its proper lordotic or curved configuration (<^>) with −Y+Z+Y force vectors while the hyper kyphotic area of the upper thoracic spine is simultaneously decompressed with a combination +Z/−Y force mid-vector and the occiputal-cervical junction is simultaneously decompressed with +Z/+Y force vectors. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the thoracic hyper-kyphosis is simultaneously reduced and the occipital-cervical junction is decompressed. In certain embodiments, 15° to 20° of forward head flexion can be imparted by the application of +Z/+Y force vectors to the occiput.

Continuous expansion and contraction of the pneumatic air chambers can be employed to create alternating hydration and milking of the intervertebral discs, activating their sponge-like imbibition action. Holding the air pressure constant over a period of 15 to 20 minutes has the effect of simultaneously molding the spine into a curved or elliptical shape, decompressing discs and relaxing the dura, cord and nerve-roots in the cervical canal.

Embodiments described herein are preferably prescribed for patients with chronic neck pain due to a musculoskeletal or neurological impairment. The system applies radial tractional force to the cervical spine, enhancing the cervical lordotic curve while achieving high level joint separation at the anterior, center and posterior aspect of the vertebral bodies and discs in a ratio corresponding with their natural wedged spacing, reducing disc protrusions, compression and increasing range of motion. The system further applies angular traction forces to the occiput, achieving decompression of the occipital-cervical junction. In some applications, devices advantageously decrease pain in chronic neck pain patients, decrease headaches and increase range of motion while reducing the necessity for chronic pain medication and neck surgery.

With continued reference to FIGS. 23A and 23B, according to some embodiments in use, the traction device 110 rests on a horizontal surface such that the neck support 128 projects upwardly therefrom. The user lies on the device in a prone position such that the back of the neck rests on the deflated first expandable bladder 116 carried in the cradle 138 of the neck support 128. The deflated second expandable bladder 118 is positioned between the neck support 128 and portions of the thoracic spine of the user. The deflated third expandable bladder 119 is positioned between the neck support 128 and the occiput of the user. The chin and/or forehead restraining restraint straps are respectively extended under the user's chin and/or about the user's forehead and secured, thereby affixing the traction device 110 to the user such that the neck and cervical spine extend over the neck support and first expandable bladder 116, the thoracic spine is adjacent the second expandable bladder 118, and the occiput is adjacent the third expandable bladder 119. According to one preferred embodiment, the outward extension of the neck support 128 is relatively slight so that when the bladder is in the deflated position with the forehead and chin restraints secured, very little or no force is exerted on the neck by the neck support. This is achieved by elevating the neck support 128 above the frame such that the neck cradle 138 formed therein is about 2 to 3 inches above the floor or other horizontal surface on which the device 110 is used. The first expandable bladder 116 is sized such that upon full inflation, the apex of the curved upper surface of the bladder will extend about 5 inches above the floor or surface. The second expandable bladder 118 is sized such that upon full inflation, a surface of the second expandable bladder engaging the thoracic spine will extend toward the thoracic spine about 2 to 3 inches in the −Y/+Z direction. In certain embodiments, the second expandable bladder 118 is sized and/or positioned such that during inflation, a surface of the second expandable bladder 118 engaging the thoracic spine will impart a force to the thoracic spine in the −Y direction during a first period of inflation and will impart a force to the thoracic spine in the −Y/+Z direction during a second period of inflation following the first period of inflation. In certain embodiments, the expandable bladder 118 is sized and/or positioned such that upon full inflation, a surface of the expandable bladder 118 engaging the thoracic spine will impart a force to the thoracic spine in the −Y direction. The third expandable bladder 119 is sized such that upon inflation, a surface of the third expandable bladder engaging the occiput will extend toward the occiput about 2 to 3 inches in the +Y/+Z direction. Upon inflation, the third expandable bladder 119 can impart 15° to 20° of forward head flexion. In certain embodiments, the third expandable bladder 119 is sized and/or positioned such that during inflation, a surface of the third expandable bladder 119 engaging the occiput will impart a force to the occiput in the +Y direction during a first period of inflation and will impart a force to the occiput in the +Y/+Z direction during a second period of inflation following the first period of inflation. In certain embodiments, the expandable bladder 119 is sized and/or positioned such that upon full inflation, a surface of the expandable bladder 119 engaging the occiput will impart a force to the thoracic spine in the +Y direction.

In some embodiments, as the user slowly inflates the first, second, and third inflatable bladders 116, 118, and 119 using the air pump 142, the first inflatable bladder 116 expands upwardly and, to a lesser extent, transversely, thereby forcing the cervical spine forwardly creating a spinal apex while concurrently stretching the spine angularly along both sides of the formed spinal apex. The second inflatable bladder 118 expands transversely in the −Y direction, thereby forcing the thoracic spine forwardly to offset the effects of hyper-khyphosis. The third inflatable platter expands transversely in the +Y direction, thereby forcing the occiput forwardly and upwardly to create radial traction to attain joint separation of the occipital-cervical junction. The user then continues to inflate the first, second, and third bladders 116, 118, and 119 until his or her individual tolerance level is reached. The bladders are then deflated by use of the one way valve 144. The process is preferably repeated several times, slowly increasing the spinal arc in the cervical region and placing pressure on the thoracic region as the level of tolerance increases. In addition, the first, second, and third bladders 116, 118, and 119 can be held in an inflated state at or slightly below the level of tolerance for varying periods of time up to ten to twenty minutes. Through such repetition, the cervical spine, thoracic spine and surrounding tissue receive a workout promoting cellular exchange in and around the intervertebral disc and a forward curve is reinstated into the cervical spine while achieving proper spine configuration in the thoracic region. FIGS. 23A and 23B illustrate the effects of the traction and exercise devices 210 of some embodiments on the cervical and thoracic spine.

With reference to FIGS. 24-27, an adjustable spacer component 150A and a spacer component 150B can be provided in some implementations of a traction system 110 to provide for lateral flexion traction. For example, FIG. 24 is a schematic top view of a patient positioned on another embodiment of a decompression and traction system, showing pneumatic air chambers comprising first, second, and third inflatable bladders 116, 118, and 119, a first adjustable wedge-shaped spacer component 150A configured to be selectively coupled to the frame to adjust a position of the second inflatable bladder, and a second adjustable wedge-shaped spacer component 150B configured to be selectively coupled to the frame to adjust a position of the third inflatable bladder. In the shown configuration, the first spacer component 150A is in a vertical orientation and adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane without providing any lateral flexion traction to the patient. In the shown configuration, the second spacer component 150B is in a vertical orientation and adjusts the position of the third inflatable bladder to provide an even distribution of force generally along a force vector in the +Y and +Z plane without providing any lateral flexion traction to the patient.

FIG. 25 shows a configuration wherein the first spacer component 150A is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force on one side of the patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction. For example, the spacer component is turned or rotated to a horizontal position, whereby the wedge shape of the spacer contacts the second inflatable bladder and causes the bladder to deflect in one lateral direction more than another lateral direction. As shown, the spacer is placed in right horizontal position and causes more deflection on the right side of the patient. In other configurations, the spacer can be positioned in a left horizontal position to cause more deflection on the left side of the patient. Based on the positioning of the spacer, the second bladder can expand in an angular direction. Turning the spacer component sideways creates lateral flexion traction by forcing the shoulder/trapezius down while the head is held in traction.

In the configuration shown in FIG. 25, the second spacer component 150B is moved to adjust the position of the third inflatable bladder to provide an uneven distribution of force on one side of the patient in that a force vector is directed, for example, in a +Y, +Z, and −X direction. For example, the spacer component is turned or rotated to a horizontal position, whereby the wedge shape of the spacer contacts the third inflatable bladder and causes the bladder to deflect in one lateral direction more than another lateral direction. As shown, the spacer is placed in right horizontal position and causes more deflection on the right side of the patient. In other configurations, the spacer can be positioned in a left horizontal position to cause more deflection on the left side of the patient. Based on the positioning of the spacer, the third bladder can expand in an angular direction. Turning the spacer component sideways creates lateral flexion traction by forcing the head up while the shoulder/trapezius is held in traction. In certain embodiments, the spacer component 150B can be moved to adjust the position of the third inflatable bladder to provide an uneven force distribution of force on one side of the patient, as described herein, to treat a misalignment or deformity of the spine which causes the cervical spine to angle or curve in the +X or −X direction. For example, if the cervical spine of a patient is angled or curved in the +X direction, a −X force can be imparted to restore the cervical spine to its proper configuration. If the cervical spine of a patient is angled or curved in the −X direction, a +X force can be imparted to restore the cervical spine to its proper configuration.

FIG. 26 is a bottom view of the embodiment of FIG. 24 and shows the spacer component 150A in a vertical position that adjusts the position of the second inflatable bladder to provide an even distribution of force generally along a force vector in the −Y and +Z plane, but does not direct force laterally in a −X or +X direction. FIG. 26 shows the spacer component 150B in a vertical position that adjusts the position of the third inflatable bladder to provide an even distribution of force generally along a force vector in the +Y and +Z plane, but does not direct force laterally in a −X or +X direction. FIG. 27 is a bottom view of the embodiment of FIG. 24, showing a configuration wherein the first spacer component 150A is moved to adjust the position of the second inflatable bladder to provide an uneven distribution of force to a patient in that a force vector is directed, for example, in a −Y, +Z, and −X direction as described in connection with FIG. 25. The lower linear displacement pneumatic air chamber is adjusted with a rotating wedge shaped spacer component, allowing clinicians to increase the angle and force of the mid (−Y)/(+Z) vector of this pneumatic air chamber. When adjusted to the right or left horizontal position, the rotating wedge allows clinicians to unilaterally increase and rotate the (−Y) directional component on either the right or left side (+/−X) of the upper thoracic region, producing lateral flexion traction. The rotating wedge shaped spacer component can be removed in some implementations to accommodate extreme kyphotic thoracic spines. In the configuration of FIG. 27, the second spacer component 150B is moved to adjust the position of the third inflatable bladder to provide an uneven distribution of force to a patient in that a force vector is directed, for example, in a +Y, Z, and −X direction as described in connection with FIG. 25. The upper linear displacement pneumatic air chamber is adjusted with a rotating wedge shaped spacer component allowing clinicians to increase the angle and force of the mid (+Y)/(+Z) vector of this pneumatic air chamber. When adjusted to the right or left horizontal position, the rotating wedge allows clinicians to unilaterally increase and rotate the (+Y) directional component on either the right or left side (+/−X) of the occiput, producing lateral flexion traction. The rotating wedge shaped spacer component can be removed in some implementations.

While three expandable bladders 116, 118, and 119 are described with respect to FIGS. 15-27, certain embodiments may employ only two of the inflatable bladders 116, 118, and 119, as shown in FIGS. 1-14, or only one of the inflatable bladders 116, 118, and 119. For example, in some embodiments, a decompression and traction system 310 may include only the first inflatable bladder 116 and the third inflatable bladder 119 as shown in FIG. 28. Such an embodiment may be less expensive to manufacture than an embodiment having three inflatable bladders. As described herein, the first inflatable bladder 116 and third inflatable bladder 119 can be employed to apply −Y+Z+Y force vectors to the cervical spine while +Z/+Y force vectors are applied to the occiput. The cervical spine's lordotic curve is powerfully decompressed and enhanced while the occipital-cervical junction is decompressed. Such an embodiment may be advantageous if treatment of the thoracic spine is not desired. For example, in some embodiments, damage to the thoracic spine or an obstruction, such as a tumor or implant, may make the application of force to the thoracic spine undesirable. The system 310 may be utilized to treat symptoms associated with compression, damage, deformity, and/or misalignment of the cervical spine and the occipital-cervical junction, including, for example, headaches, neck pain, and arm pain, which may be caused by pinched nerves. In certain embodiments, the decompression and traction system 310 can include a spacer component 150B as described with respect to the decompression and traction system 210 as shown in FIGS. 15-27.

In some embodiments, a similar application of force can be imparted by the system 210 through selective inflation of the bladders 119 and 116 without inflation of the bladder 118 or with minimal inflation of the bladder 118. As described herein, in some embodiments, a two pump system or a three pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. For example, in some embodiments, a first pump can be employed to inflate the first and third inflatable bladders 116 and 119 and a second pump can be employed to inflate the second inflatable bladder 118.

In some embodiments, a decompression and traction system 410 may include only the second inflatable bladder 118 and the third inflatable bladder 119 as shown in FIG. 29. Such an embodiment may be less expensive to manufacture than an embodiment having three inflatable bladders. In some embodiments, the system 410 includes a pad or cushion 436 configured to be positioned against the cervical spine when the system 410 is secured to a user. As described herein, the second bladder 118 and third inflatable bladder 119 can be employed to decompress a hyper kyphotic area of the upper thoracic spine with a combination +Z/−Y force mid-vector while +Z/+Y force vectors are simultaneously applied to the occiput to decompress the occipital-cervical junction. Thoracic hyper-kyphosis is simultaneously reduced while the occipital-cervical junction is decompressed. In certain embodiments, the second inflatable bladder 118 can be employed to apply a −Y force vector to the upper thoracic spine, and the third inflatable bladder 119 can be employed to apply a +Y force vector to the occipital-cervical junction. In some embodiments, the system 310 can be used to impart linear traction to the spine. In certain embodiments, the decompression and traction system 410 can include a spacer component 150A as described with respect to the decompression and traction system 210 as shown in FIGS. 15-27. In certain embodiments, the decompression and traction system 410 can include a spacer component 150B as described with respect to the decompression and traction system 210 as shown in FIGS. 15-27.

In some embodiments, a similar application of force can be imparted by the system 210 through selective inflation of the bladders 119 and 118 without inflation of the bladder 116 or with minimal inflation of the bladder 116. As described herein, in some embodiments, a two pump system or a three pump system can be employed to alternate or unevenly inflate the pneumatic air chambers. For example, in some embodiments, a first pump can be employed to inflate the second and third inflatable bladders 118 and 119 and a second pump can be employed to inflate the first inflatable bladder 116. By inflating the bladders 119 and 118 without inflating the bladder 116 or with minimal inflation of the bladder 116, linear traction can be imparted to the spine.

FIG. 30 shows a patient and an embodiment of a decompression and traction system 510 having an elongated inflatable bladder 518. The elongated inflatable bladder 518 can extend from the neck support to the mid-thoracic spine when the decompression and traction system 510 is secured to the user. In some embodiments as described herein, the mid-thoracic spine can include the T4-T9 vertebrae, the T5-T8 vertebrae, or the T6-T7 vertebrae. In addition to the application of forces to the upper thoracic spine, as described herein, the inflatable bladder 518 can be configured for inflation and simultaneous application of force to the mid-thoracic spine, when the patient is in a treatment position, to decompress the spine into its proper curved configuration with a +Z force vector, and in some embodiments, −Y and/or +Y for force vectors, being applied to the mid-thoracic spine. The elongated inflatable bladder 518 can apply pressure to the apex of the kyphosis of the thoracic spine. In some embodiments, the thoracic hyper-kyphosis can be further reduced by the application of force to the mid-thoracic spine. The elongated bladder 518 can directly contact the upper 25%-75% of the thoracic spine. In certain embodiments, the elongated bladder 518 can directly contact the upper 25% to 45%, upper 25% to 50%, upper 25% to 55%, upper 25% to 60%, upper 25% to 65%, or upper 25% to 70% of the thoracic spine. In certain embodiments, the elongated bladder 518 can directly contact the upper 50% of the thoracic spine.

As described herein, the inflatable bladder 518 can be inflated using a pump assembly. A pump for inflation of the inflatable bladder 518 can be the same as or a separate pump from one or more pumps used for inflation of the inflatable bladders 116 and 119. In some embodiments, two or more pumps can be employed to alternate or unevenly inflate portions of the elongated inflatable bladder 518. For example, in some embodiments, a first pump can be employed to inflate a first portion of the elongated inflatable bladder 518 positioned to apply a force to the upper thoracic spine and a second pump can be employed to inflate a second portion of the elongated inflatable bladder 518 positioned to apply a force to the mid-thoracic spine. Although a single elongated inflatable bladder 518 is shown in FIG. 30, in some embodiments, a separate inflatable bladder may be employed to apply a force to the mid-thoracic spine. In such embodiments, the separate inflatable bladder configured to apply a force to the mid-thoracic spine can be inflated using a pump that can be separate from or shared with the inflatable bladder positioned to apply a force to the upper thoracic spine.

In certain embodiments, the decompression and traction system 510 can include one or more spacer components having the same or similar features to spacer components 150, 150A, and 150B. For example, in some embodiments, the decompression and traction system 510 can include a spacer between a portion of the frame 112 and the elongated inflatable bladder 518. The spacer can be employed to adjust the angulation of the inflatable bladder 518 during inflation. In certain embodiments, the decompression and traction system 510 can include a spacer between a portion of the frame 112 and the inflatable bladder 119. The spacer can be employed to adjust the angulation of the inflatable bladder 119 during inflation. Spacers used in the decompression and traction system 510 can include a wedge-shaped spacer, a rotatable spacer, and/or a spacer in a horizontal position that is configured to adjust the angulation of the inflatable bladder portion 119 or the inflatable bladder portion 518 during inflation to provide lateral flexion traction. Other spacer systems are contemplated and can also be used. For example, any component or device that can be selectively adjusted and can contact at least a portion of the inflatable bladder portion 119 and/or the inflatable bladder portion 518 can be used to impart lateral flexion traction. Additionally, in some cases a component or device need not be adjustable, for example, a spacer or other component could be provided on a traction device to cause the inflatable bladder portion 119 and/or the inflatable bladder portion 518 to consistently provide for lateral flexion traction on one side, while other systems can provide for lateral flexion traction on the other side. Additionally, while adjustments made with the spacer may be rotational, other movements or adjustments can be made with other mechanisms and arrangements, such as by sliding, for example.

While three expandable bladders 116, 518, and 119 are described with respect to FIG. 30, certain embodiments may employ only the elongated inflatable bladder portion 518 or only the elongated inflatable bladder portion 518 and one of the inflatable bladder portion 116 and the inflatable bladder portion 119.

The various devices, systems and methods described above provide a number of ways to carry out some preferred embodiments of the invention. Of course, it is to be understood that not necessarily all objectives or advantages described may be achieved in accordance with any particular embodiment described herein. Thus, for example, those skilled in the art will recognize that the devices and systems may be made and the methods may be performed in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other objectives or advantages as may be taught or suggested herein.

Furthermore, the skilled artisan will recognize the interchangeability of various features from different embodiments. Similarly, the various components, features and steps discussed above, as well as other known equivalents for each such component, feature or step, can be mixed and matched by one of ordinary skill in this art to make devices and systems and perform methods in accordance with principles described herein.

Although the invention has been disclosed in the context of some embodiments and examples, it will be understood by those skilled in the art that the invention extends beyond these specifically disclosed embodiments to other alternative embodiments and/or uses and obvious modifications and equivalents thereof. Accordingly, the invention is not intended to be limited by the specific disclosures of preferred embodiments herein. 

What is claimed is:
 1. A traction device comprising: a frame having a base and a neck support coupled to the base to support the neck of a user during use; a first inflatable bladder coupled to the neck support, the first inflatable bladder configured to expand in an outward direction from the neck support toward the neck of a user and expandable in a transverse direction substantially normal to the outward direction upon inflation; a second inflatable bladder coupled to the neck support and configured to expand in a first angular direction from the neck support, the second inflatable bladder being positioned generally inferior to the first inflatable bladder; and a third inflatable bladder coupled to the neck support and configured to expand in a second angular direction from the neck support, the third inflatable bladder being positioned generally superior to the first inflatable bladder; whereby upon the first inflatable bladder expanding in the outward direction, the first inflatable bladder bears outwardly against the back of the neck of the user as the first inflatable bladder is inflated and forces the cervical spine to curve forwardly, and upon expanding in the transverse direction, the first inflatable bladder applies an angular traction to the cervical spine as the first inflatable bladder is inflated; whereby upon the second inflatable bladder expanding in the first angular direction, the second inflatable bladder bears angularly against the back of the upper thoracic region of the user as the second inflatable bladder is inflated and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine; and whereby upon the third inflatable bladder expanding in the second angular direction, the third inflatable bladder bears angularly against the occiput of the user as the third inflatable bladder is inflated to decompress the occipital-cervical junction; wherein the first inflatable bladder is positioned anteriorly to the second inflatable bladder and the third inflatable bladder; and wherein the shape of the second inflatable bladder corresponds to the shape of the third inflatable bladder.
 2. The traction device of claim 1, further comprising a spacer configured to be coupled between a portion of the frame and the second inflatable bladder to adjust the angulation of the second inflatable bladder during inflation.
 3. The traction device of claim 1, further comprising a spacer configured to be coupled between a portion of the frame and the third inflatable bladder to adjust the angulation of the third inflatable bladder during inflation.
 4. The traction device of claim 3, wherein the spacer is a wedge-shaped spacer.
 5. The traction device of claim 3, wherein the spacer is rotatable.
 6. The traction device of claim 1, comprising one or more pumps for selectively inflating one or more of the first inflatable bladder, the second inflatable bladder, and the third inflatable bladder.
 7. The traction device of claim 6, further comprising a valve positioned in communication with the one or more pumps and the first inflatable bladder, the second inflatable bladder, and the third inflatable bladder, wherein the valve comprises varying lumen diameters that direct flow between the one or more pumps and the first inflatable bladder, the second inflatable bladder, and the third inflatable bladder.
 8. A traction device comprising: a frame having a base and a neck support coupled to the base to support the neck of a user during use; a first inflatable bladder coupled to the neck support, the first inflatable bladder configured to expand in an outward direction from the neck support toward the neck of the user and expandable in a transverse direction substantially normal to the outward direction upon inflation; a second inflatable bladder coupled to the neck support and configured to expand in a first angular direction from the neck support, the second inflatable bladder being positioned generally inferior to the first inflatable bladder; and a third inflatable bladder coupled to the neck support and configured to be positioned superior to the first inflatable bladder, the third inflatable bladder being expandable in a second angular direction from the neck support toward a occiput of the user upon inflation; whereby upon the first inflatable bladder expanding in the outward direction, the first inflatable bladder bears outwardly against the back of the neck of the user as the first inflatable bladder is inflated and forces the cervical spine to curve forwardly, and upon expanding in the transverse direction, the first inflatable bladder applies an angular traction to the cervical spine as the first inflatable bladder is inflated; whereby upon the second inflatable bladder expanding in the first angular direction, the second inflatable bladder bears angularly against the back of the upper thoracic region of the user as the second inflatable bladder is inflated and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine; and whereby upon the third inflatable bladder expanding in the angular direction, the third inflatable bladder bears angularly against the occiput of the user as the third inflatable bladder is inflated to decompress the occipital-cervical junction; wherein the first inflatable bladder is positioned anteriorly to the second inflatable bladder and the third inflatable bladder; and wherein first inflatable bladder is of a first shape and the second inflatable bladder and the third inflatable bladder are of a second shape different than the first shape.
 9. The traction device of claim 8, further comprising a spacer configured to be coupled between a portion of the frame and the second inflatable bladder to adjust the angulation of the second inflatable bladder during inflation.
 10. The traction device of claim 9, wherein the spacer is a wedge-shaped spacer.
 11. The traction device of claim 9, wherein the spacer is rotatable.
 12. The traction device of claim 8, comprising one or more pumps for selectively inflating one or more of the first and second inflatable bladders.
 13. The traction device of claim 12, further comprising a valve positioned in communication with the one or more pumps and the first and second inflatable bladders, wherein the valve comprises varying lumen diameters that direct flow between the one or more pumps and the first and second inflatable bladders.
 14. A traction device comprising: a frame having a base and a neck support coupled to the base to support the neck of a user during use; a first inflatable bladder coupled to the neck support, the first inflatable bladder configured to expand in a first angular direction from the neck support; a second inflatable bladder coupled to the neck support and configured to be positioned superior to the first inflatable bladder, the second inflatable bladder being expandable in a second angular direction from the neck support toward a occiput of the user upon inflation; and a pad coupled to the neck support and configured to be positioned against the cervical spine, the pad being positioned between the first inflatable bladder and the second inflatable bladder; whereby upon the first inflatable bladder expanding in the first angular direction, the first inflatable bladder bears angularly against the back of the upper thoracic region of the user as the first inflatable bladder is inflated and forces the thoracic spine to decompress and reduces hyper-kyphosis of the upper thoracic spine; whereby upon the second inflatable bladder expanding in the second angular direction, the second inflatable bladder bears angularly against the occiput of the user as the second inflatable bladder is inflated to decompress the occipital-cervical junction.
 15. The traction device of claim 14, further comprising a spacer configured to be coupled between a portion of the frame and the second inflatable bladder to adjust the angulation of the second inflatable bladder during inflation.
 16. The traction device of claim 15, wherein the spacer is a wedge-shaped spacer.
 17. The traction device of claim 15, wherein the spacer is rotatable.
 18. The traction device of claim 14, comprising one or more pumps for selectively inflating one or more of the first and second inflatable bladders.
 19. The traction device of claim 18, further comprising a valve positioned in communication with the one or more pumps and the first and second inflatable bladders, wherein the valve comprises varying lumen diameters that direct flow between the one or more pumps and the first and second inflatable bladders.
 20. The traction device of claim 14, wherein upon the first inflatable bladder expanding in the first angular direction and the second inflatable bladder expanding the second angular direction, the first inflatable bladder and second inflatable bladder impart linear traction to the spine of the user.
 21. A method of treating a spine, the method comprising the steps of: securing a traction device to a head of a user, the traction device comprising a support frame having a transverse neck support projecting upwardly from a base of the support frame and first, second, and third inflatable bladders coupled to the neck support, wherein securing the traction device to the head comprises positioning the traction device such that: the first inflatable bladder transverses a cervical spine of the user; the second inflatable bladder transverses an upper thoracic spine of the user; and the third inflatable bladder transverses an occiput of the user; expanding the first inflatable bladder in a direction outward from the neck support and toward and substantially normal to the cervical spine to force the cervical spine to curve forwardly; expanding the second inflatable bladder in a direction toward the upper thoracic spine to force the thoracic spine to decompress and reduce hyper-kyphosis of the upper thoracic spine; and expanding the third inflatable bladder in a direction toward the occiput to apply an angular traction to a cervical spine of the user; wherein the first inflatable bladder is positioned anteriorly to the second inflatable bladder and the third inflatable bladder; and wherein the shape of the second inflatable bladder corresponds the shape of the third inflatable bladder.
 22. The method of claim 21, comprising the step of alternately inflating and deflating the first, second, and third bladders.
 23. The method of claim 22, comprising the step of repeating inflation and deflation of the first, second, and third bladders.
 24. The method of claim 21, wherein at least one of the first, second, and third inflatable bladders has a semi-ellipsoidal configuration upon inflation.
 25. The method of claim 21, wherein the traction device comprises a valve positioned in communication with one or more pumps, the first inflatable bladder, and the second inflatable bladder, wherein the method further comprises directing flow from the one or more pumps through the valve to the first inflatable bladder and the second inflatable bladder. 